Representing traffic along a route

ABSTRACT

Some embodiments provide a mapping application that has a novel way of displaying traffic congestion along roads in the map. The mapping application in some embodiments defines a traffic congestion representation to run parallel to its corresponding road portion when the map is viewed at a particular zoom level, and defines a traffic congestion representation to be placed over its corresponding road portion when the map is viewed at another zoom level. The mapping application in some embodiments differentiates the appearance of the traffic congestion representation that signifies heavy traffic congestion from the appearance of the traffic congestion representation that signifies moderate traffic congestion. In some of these embodiments, the mapping application does not generate a traffic congestion representation for areas along a road that are not congested.

This application claims benefit to U.S. Provisional Patent Application61/657,860, filed Jun. 10, 2012; U.S. Provisional Patent Application61/699,799, filed Sep. 11, 2012; U.S. Provisional Patent Application61/699,855, filed Sep. 11, 2012; and U.S. Provisional Patent Application61/657,880, filed Jun. 10, 2012. U.S. Provisional Patent Applications61/657,860 and 61/699,799 are incorporated herein by reference.

BACKGROUND

FIG. 1 conceptually illustrates a known approach of generating anavigation map with traffic information. This figure illustrates thatone approach for displaying traffic data on a map is by overlayingtraffic information over pre-rendered static raster images thatrepresent different portions of the map. To illustrate this approach,this figure illustrates a generated map section 110, a traffic dataobject 120, and a static road tile 130.

The static road image 130 is a pre-rendered raster image of the section110 of a map. It is a two-dimensional graphic representation of ageographical area. The road image 130 may show roads, landmarks, naturalfeatures of the geographical area (such as hills, mountains, bodies ofwater, vegetation, coastline), and man-made structures (such asbuildings, bridges, etc.). The road image 130 may also include labels onit (such as names of streets, locations, etc.) to help specify alocation.

The traffic data object 120 includes static and dynamic traffic data forthe roads that are part of the static road tile 130. This informationmay include road conditions such as traffic congestion, detours, andtraffic accidents. It also includes information that describes thelayout of the roads in the static road tile 130.

The dynamic traffic data 120 is applied to the static road image 130 togenerate the map section 110 that shows the traffic information alongthe roads that are part of the map section. The map section 110 is aportion of the map that is generated with other sections for display.

The traditional approach of overlaying the traffic data over the staticroad image 130 to display traffic data on a section of a map has severaldisadvantages. One disadvantage is that the traffic data does not alwaysperfectly match the road layout at all zoom levels for showing themapping at different levels of details. Another disadvantage is that therepresentation of traffic data often occludes the detail (e.g., namesand structure of roads) that is part of the static road image. Yetanother disadvantage of this approach is that the traffic data 120 istightly coupled to the static road image 130. Every time a client deviceupgrades to a new version of the static road image, the traffic serverhas to upgrade the traffic data 120 accordingly. Furthermore, since someclient devices may not upgrade to the latest version of the static roadimage or may not upgrade at all, the traffic server has to supportmultiple versions of static road images.

BRIEF SUMMARY

Some embodiments of the invention provide a mapping application thatincludes several novel techniques to provide traffic data. In someembodiments, the novel features of the mapping application include (1)techniques for rendering traffic data for display by the mappingapplication, (2) techniques for representing and highlighting traffic onroutes, and (3) a data structure for expressing traffic data andassociating such data with road data that is used to render roads fordisplay by the mapping application. In some embodiments, the mappingapplication also employs a novel encoding scheme for expressing routesin a compressed manner.

In some embodiments, the mapping application identifies a segment oftraffic congestion, correlates this traffic segment to a portion of aroad in the map area that corresponds to the traffic segment, and usesthat portion's definition to define a traffic congestion representationfor the traffic segment. The mapping application then uses roaddefinition portion and the traffic congestion representation toconcurrently render the road and traffic representation. In someembodiments, the mapping application can provide a three-dimensional(3D) perspective view of the map. When providing such a 3D perspectiveview, the mapping application uses the road definition portion and thetraffic congestion portion to define road and traffic congestionfeatures in a 3D scene that it renders from the particular perspectiveview. In some such embodiments, the mapping application defines avirtual camera to represent the 3D perspective view. This virtual camerais moveable by the user or by other processes of the mapping applicationto define new perspective view of the same road portion and trafficcongestion or of different road portion and traffic congestion.

To facilitate the correlation of the static road data with the dynamictraffic data, the mapping application of some embodiments uses a noveldata structure scheme. In this scheme, a linking layer is defined tocorrelate roads that are defined in the static road data structures totraffic congestion segments that are defined in the dynamic trafficdata.

For a particular view of the map, the mapping application of some ofthese embodiments identifies the relevant static road data structure(s),linking data structure(s), and dynamic traffic data structure(s). Itthen uses the linking data structure(s) to identify the correspondingroad portion for each traffic congestion segment in each identifieddynamic traffic data structure. The mapping application then uses theroad portion corresponding to each traffic congestion segment to definetraffic representation for the traffic congestion segment. The mappingapplication then renders concurrently the road portion and the trafficrepresentation.

In some embodiments, the mapping application defines each trafficrepresentation to run parallel to its corresponding road portion, whilein other embodiments it defines each traffic representation to be placedover its corresponding road portion. Yet other embodiments employ bothsuch approaches depending on the zoom level at which the map is beingviewed. For instance, in some embodiments, the mapping applicationdefines a traffic representation to run parallel to its correspondingroad portion when the road portion is too narrow at a zoom level, whiledefining the traffic representation to lie over its corresponding roadportion when the road portion is not too narrow at another zoom level.

Some embodiments of the invention provide a novel encoding scheme forexpressing routes in a compressed manner. In some embodiments, a routeserver encodes or compresses routes by removing unnecessary controlpoints from the routes. A control point in some embodiments is a pieceof data (e.g., maneuver instruction) that specifies a road segment towhich to advance from a juncture of the route. A juncture is a locationin a map where two or more road segments meet. The route server providescompressed routes to route clients that decode the routes.

The route server in some embodiments generates a route from a startingpoint to an ending point with a control point at every juncture. Theroute server then determines, for every control point in the route,whether the control point is necessary. The route server removesunnecessary control points from the routes and sends the routes to theroute clients.

The route clients in some embodiments include a mapping application,which generates directions for a user by decoding the compressed routes.In some cases, the map data that the route server used to generate thecompressed routes is not the same map data that the mapping applicationuses to decode the compressed routes. The mapping application employs anovel method of rendering the routes on a map even if the map data usedby the route server and the map data used by the mapping application donot match.

In some cases, the mapping application sends a compressed route toanother server for further analysis (e.g., ETA to the ending location).In some embodiments, the mapping application of some embodiments reducesthe compressed route to send to the other server by removing controlpoints that have been consumed by the mapping application.

The preceding Summary is intended to serve as a brief introduction tosome embodiments of the invention. It is not meant to be an introductionor overview of all inventive subject matter disclosed in this document.The Detailed Description that follows and the Drawings that are referredto in the Detailed Description will further describe the embodimentsdescribed in the Summary as well as other embodiments. Accordingly, tounderstand all the embodiments described by this document, a full reviewof the Summary, Detailed Description and the Drawings is needed.Moreover, the claimed subject matters are not to be limited by theillustrative details in the Summary, Detailed Description and theDrawing, but rather are to be defined by the appended claims, becausethe claimed subject matters can be embodied in other specific formswithout departing from the spirit of the subject matters.

BRIEF DESCRIPTION OF THE DRAWINGS

The novel features of the invention are set forth in the appendedclaims. However, for purposes of explanation, several embodiments of theinvention are set forth in the following figures.

FIG. 1 conceptually illustrates a known approach of generating anavigation map with traffic information.

FIG. 2 illustrates an example of a device that executes an integratedmapping application of some embodiments of the invention.

FIG. 3 illustrates how the navigation application of some embodimentsprovides the 3D control as a quick mechanism of entering a 3D navigatingmode.

FIG. 4 presents a simplified example to illustrate the concept of avirtual camera.

FIG. 5 illustrates how some embodiments turn on the traffic services anddisplay traffic data on a map view of the integrated mapping applicationof some embodiments of the invention.

FIG. 6 illustrates another way that some embodiments use to turn on thetraffic services and display traffic data on a map view of theintegrated mapping application of some embodiments of the invention.

FIG. 7 illustrates yet another way that some embodiments use to turn onthe traffic services.

FIG. 8A illustrates an example of the user browsing an area about themap view.

FIG. 8B illustrates another example of the user browsing a mapping toview traffic data.

FIG. 9A illustrates an example of the user inspecting alternative routesthat are displayed on the map view to identify the least congestedroute.

FIG. 9B pictorially shows the darkening and/or de-saturation of thetraffic patterns in terms of line markers.

FIG. 10A illustrates an example of displaying traffic condition.

FIG. 10B illustrates a device with a larger screen showing trafficcondition.

FIG. 10C-10E respectively illustrates how the mapping application ofsome embodiments shows ramp closings, hazardous conditions and accidentsalong a map.

FIG. 10F illustrates a 3D perspective view of a map.

FIG. 10G presents another example of rendering traffic representationsin order to further illustrate how the mapping application treatstraffic representations as just another object in a 3D scene that itrenders.

FIG. 11A conceptually illustrates a data structure to express trafficdata and associate this data with road data.

FIG. 11B illustrates a more detailed example of a data structure that isused to represent a road and the traffic associated with differentsegments of the road.

FIG. 12 provides a conceptual illustration of how the data in a dynamictraffic object and its associated linking traffic object provide thedata necessary for rendering the traffic for a particular road segmentor set of road segments.

FIG. 13 conceptually illustrates for some embodiments how each entry oflinking objects are mapped to geometry data of corresponding roadobjects and how traffic congestion patterns are specified for differentportions of a road.

FIG. 14 presents a process that conceptually illustrates the operationsof a traffic mesh builder that is directed by a traffic tile provider tobuild a mesh that specifies the traffic congestion for a particular viewof the map.

FIG. 15 conceptually illustrates how the linking objects make thetraffic server version independent.

FIG. 16 illustrates an exemplary hierarchical structure that organizesstatic road tiles at different zoom levels in a quadtree.

FIG. 17A further illustrates the concept of providing traffic data at asingle zoom level and applying it to static road tiles and linking tilesfor a range of zoom levels.

FIG. 17B illustrates a conceptual illustration of an alternativerendering pipeline of the mapping application for some embodiments ofthe invention.

FIG. 18 illustrates conceptual representations of a route generated bythe route server of some embodiments.

FIG. 19 conceptually illustrates a process of some embodiments forencoding route representations as a minimum number of control points.

FIGS. 20 and 21 illustrate four example junctures.

FIG. 22 conceptually illustrates a process of some embodiments fordecoding route representations that has been encoded as a minimum numberof control points.

FIG. 23 conceptually illustrates a process that some embodiments performto render a route on a map in order to display the route representationon a device that the mapping application runs.

FIG. 24 conceptually illustrates an example of rendering a route at twodifferent zoom levels.

FIG. 25 conceptually illustrates an example of sending compressed routedata (1) from a route server that generates the compressed route to afirst client that consumes the compressed route data and then (2) fromthe first client to a second client that consumes the compressed routedata.

FIG. 26 is an example of an architecture of a mobile computing device onwhich the mapping application of some embodiments operates.

FIG. 27 conceptually illustrates another example of an electronic systemwith which some embodiments of the invention are implemented.

FIG. 28 illustrates a map service operating environment, according tosome embodiments.

DETAILED DESCRIPTION

In the following detailed description of the invention, numerousdetails, examples, and embodiments of the invention are set forth anddescribed. However, it will be clear and apparent to one skilled in theart that the invention is not limited to the embodiments set forth andthat the invention may be practiced without some of the specific detailsand examples discussed.

Some embodiments of the invention provide a mapping application thatincludes several novel techniques to provide traffic data. In someembodiments, the application executes on a device (e.g., a mobiledevice) that has a touch-sensitive screen that displays the output ofthe application, and a multi-touch interface that allows a user toprovide touch and gestural inputs through the screen to interact withthe application. In other embodiments, the application executes on adevice that does not have a touch-sensitive screen.

In some embodiments, the novel features of the mapping applicationinclude (1) techniques for rendering traffic data for display by themapping application, (2) techniques for representing and highlightingtraffic on routes, and (3) a data structure for expressing traffic dataand associating such data with road data that is used to render roadsfor display by the mapping application. In some embodiments, the mappingapplication also employs a novel encoding scheme for expressing routesin a compressed manner.

In several embodiments described below, these features are part of anintegrated mapping application that provides several other usefuloperations, including location browsing, map searching, routeidentifying, and route navigation operations. However, in otherembodiments, the mapping application does not employ all of thesefeatures. For instance, in some embodiments, the mapping applicationdoes not provide route navigation.

Section I below describes the mapping application of some embodiments ofthe invention and the novel ways that it represents and highlightstraffic data in some embodiments. Section II then describes the noveldata structure that the mapping application of some embodiments uses toexpress traffic data and associate this data with road data. Section IIfurther describes the rendering of the traffic and road data to generatea display of a map with traffic data. Section III describes the encodingand decoding of routes in some embodiments of the invention. Section IVthen describes electronic devices that employ the mapping application ofsome embodiments. Section V lastly describes location services used bysome embodiments of the invention.

In the following detailed description of the invention, numerousdetails, examples, and embodiments of the invention are set forth anddescribed. However, it will be clear and apparent to one skilled in theart that the invention is not limited to the embodiments set forth andthat the invention may be practiced without some of the specific detailsand examples discussed.

I. Mapping Application

A. In General

1. Integrated Application with Multiple Features

The integrated mapping application of some embodiments includes severaluseful modalities, including location browsing, map searching, routeidentifying and route navigating operations. This integrated application(referred to below as the mapping application, the navigationapplication or the integrated application) in some embodiments isdefined to be executed by a device that has a touch-sensitive screenthat displays the output of the application. In some embodiments, thisdevice has a multi-touch interface for allowing a user to provide touchand gestural inputs through the screen to interact with the application.Examples of such devices are smartphones (e.g., iPhone® sold by AppleInc., phones operating the Android® operating system, phones operatingthe Windows 8® operating system, etc.).

FIG. 2 illustrates an example of a device 200 that executes anintegrated mapping application of some embodiments of the invention.This figure also illustrates an example of launching a route navigationin this application. This application has a novel user interface (UI)design that seamlessly and cohesively integrates the controls for eachof its different modalities by using a minimum number of on-screencontrols that float on top of the content in order to display as much ofthe content as possible. Additionally, this cluster adapts to the taskat hand, adjusting its contents in an animated fashion when a user movesbetween the different modalities (e.g., between browsing, searching,routing and navigating). This common element with an adaptive natureenables the mapping application to optimize for different tasks whilemaintaining a consistent look and interaction model while moving betweenthose tasks.

FIG. 2 shows six stages 205, 210, 215, 217, 219, 221 of interaction withthe mapping application. The first stage 205 shows the device's UI 220,which includes several icons of several applications in a dock area 225and on a page of the UI. One of the icons on this page is the icon forthe mapping application 230. The first stage shows a user's selection ofthe mapping application through touch contact with the device's screenat the location of this application on the screen.

The second stage 210 shows the device after the mapping application hasopened. As shown in this stage, the mapping application's UI has astarting page that in some embodiments displays (1) a map of the currentlocation of the device, and (2) several UI controls, arranged in a topbar 240 and as floating controls. As shown in FIG. 2, the floatingcontrols include an indicator 245, a 3D control 250, and a page curlcontrol 255, while the top bar 240 includes a direction control 260, asearch field 265, and a bookmark control 270.

In some embodiments, a user can initiate a search by tapping in thesearch field 265. This directs the application to present an animationthat (1) presents an on-screen keyboard and (2) opens a search tablefull of invaluable completions. This table has some importantsubtleties. When the search field is tapped and before the terms areedited, or when the search field is empty, the table contains a list of“recents,” which in some embodiments are recent searches and routedirections that the user has requested. This makes it very easy toquickly bring up recently accessed results.

After any input in the search field, the table is filled with searchcompletions both from local sources (e.g., bookmarks, contacts, recentsearches, recent route directions, etc.) and remote servers. Theincorporation of the user's contact card into the search interface addsadditional flexibility to the design. When showing recents, a route fromthe current location to the user's home is always offered in someembodiments, while it is offered in the contexts that are deemed to be“appropriate” in other embodiments. Also, when the search term matchesat least part of an address label (e.g. ‘ork’ for ‘Work’), theapplication presents the user's labeled address as a completion in thesearch table in some embodiments. Together these behaviors make thesearch UI a very powerful way to get results onto a map from a varietyof sources. In addition to allowing a user to initiate a search, thepresence of the text field in the primary map view in some embodimentsalso allows users to see the query corresponding to search results onthe map and to remove those search results by clearing the query.

The bookmark control 270 (e.g., button) allows locations and routes tobe bookmarked by the application. The position indicator 245 allows thecurrent position of the device to be specifically noted on the map. Whenthis indicator is selected once, the application maintains the currentposition of the device in the center of the map. In some embodiments, itcan also identify the direction to which the device currently points.

The 3D control 250 is a control for viewing the map or inspecting aroute in three dimensions (3D). The mapping application provides the 3Dcontrol as a quick mechanism of getting into and out of 3D. This controlalso serves as (1) an indicator that the current view is a 3D view, (2)an indicator that a 3D perspective is available for a given map view(e.g., a map view that is zoomed out might not have a 3D viewavailable), (3) an indicator that a 3D perspective is not available(e.g., the 3D data is not available for the map region), and (4) anindicator that a flyover animation is available at the given zoom level.The 3D control may provide a different appearance corresponding to eachindication. For instance, the 3D control may be colored grey when the 3Dview is unavailable, black when the 3D view is available but the map isin the 2D view, and blue when the map is in the 3D view. In someembodiments, the 3D control changes to an image of a building when theflyover animation is available for the user's given zoom level andlocation on the map. Flyover animation is further described inconcurrently filed U.S. Non-Provisional Patent Application Ser. No.13/632,132, entitled “Integrated Mapping and Navigation Application”.This concurrently filed application is incorporated herein by reference.

The page curl control 255 is a control that allows the application tominimize the number of on-screen controls, by placing certain lessfrequently used actions in a secondary UI screen that is accessiblethrough the page curl control that is displayed on the map. In someembodiments, the page curl is permanently displayed on at least some ofthe map views that the application provides. For instance, in someembodiments, the application displays the page curl permanently on thestarting page (illustrated in the second stage 210) that it provides forallowing a user to browse or search for a location or to identify aroute.

The direction control 260 opens a direction entry page 280 through whicha user can request a route to be identified between a starting locationand an ending location. The third stage 215 of FIG. 2 illustrates thatthe selection of the direction control 260 opens the direction entrypage 280, which is shown in the fourth stage 217. The direction controlis one of three mechanisms through which the mapping application can bedirected to identify and display a route between two locations; the twoother mechanisms are (1) a control in an information banner that isdisplayed for a selected item in the map, and (2) recent routesidentified by the device that are displayed in the search field 265.Accordingly, the information banner control and the search field 265 aretwo UI tools that the application employs to make the transition betweenthe different modalities seamless.

The fourth stage 217 shows that the direction entry page 280 includesstarting and ending fields for providing starting and ending locationsfor a route, and a table that lists recent routes that the applicationhas provided to the user. Other controls on this page are controls forstarting a route, for reversing the order of the start and endlocations, for canceling the direction request, and for picking walking,auto, or public transit routes. These controls and other aspects of themapping application are described in U.S. Provisional Patent ApplicationNo. 61/656,080, entitled “Integrated Location Browsing, Map Searching,Route Identifying, and Route Navigating Application,” and U.S.Provisional Patent Application 61/699,842, entitled “Integrated Mappingand Navigation Application.” These two provisional applications areincorporated herein by reference. These controls and other aspects ofthe mapping application are further described in U.S. patent applicationSer. No. 13/632,102, entitled “Problem Reporting in Maps,” filedconcurrently with this application. This concurrently filed applicationis incorporated herein by reference.

The fourth stage illustrates the user selecting one of the recentdirections that was auto-populated in the table 282. The fifth stage 219then shows three routes on a 2D map view between the specified start andend locations specified through the page 280. It also shows theselection of the second route and some information about this route in abar at the top of the layout. This bar is shown to include start and endbuttons. The start button is shown to be selected in the fifth stage.

As shown in the sixth stage, the selection of the start button directsthe application to enter a turn-by-turn navigation mode. In thisexample, the application has entered a 2D turn-by-turn navigation mode.In other embodiments, the application will enter by default into a 3Dturn-by-turn navigation mode. In this mode, the application displays arealistic sign 284 that identifies the distance from the currentlocation of the device to the next juncture maneuver in the navigatedroute and some other pertinent information. The application alsodisplays a top bar that includes some information about the navigation,as well as End and Overview buttons, for respectively ending thenavigation and obtaining an overview of the remaining portion of thenavigated route or the entire portion of the navigated route in otherembodiments.

The mapping application of some embodiments identifies the location ofthe device using the coordinates (e.g., longitudinal, altitudinal, andlatitudinal coordinates) in the GPS signal that the device receives atthe location of the device. Alternatively or conjunctively, the mappingapplication uses other methods (e.g., cell tower triangulation) tocompute the current location. When the user carrying the device deviatesfrom the route, the mapping application of some embodiments tracks thelocation of the device and re-calculates a new route from the deviatedlocation in order to re-direct the user to the destination location fromthe deviated location. In other words, the mapping application of someembodiments operating in the navigation mode requires the device to beon a route at all times.

The application further displays the floating 3D control and thefloating list control, which were described above. It should be notedthat the list control was adaptively added to the floating controlcluster upon entering the route inspection and route navigationmodalities, while the position indicator was removed from the floatingcontrol upon entering the route navigation modality. Also, upontransition from the route inspection mode to the route navigation mode,the application performs an animation in some embodiments that involvesthe page curl uncurling completely before the application transitionsinto the navigation presentation.

In some embodiments, the animation transition includes removing the topbar, its associated controls and the floating controls from thenavigation presentation, and moving the sign 284 to the top edge of thepresentation a short time period after starting the navigationpresentation. As further described below, the application requires theuser to tap on the navigated map to bring back the top bar, its controlsand the floating controls, and requires another tap to remove thesecontrols again from the map, in some embodiments. Other embodimentsprovide other mechanisms for viewing and removing these controls.

2. 2D and 3D Navigation

The navigation application of some embodiments can display a navigationpresentation in either a 2D mode or a 3D mode. As mentioned above, oneof the floating controls is the 3D control 250 that allows a user toview a navigation presentation in three dimensions (3D). FIG. 3illustrates how the navigation application of some embodiments providesthe 3D control 250 as a quick mechanism for entering a 3D navigatingmode. This figure illustrates this operation in three stages 305-315.The first stage 305 illustrates the user selecting the 3D control 250while viewing a two-dimensional navigation presentation.

The second stage 310 illustrates the navigation presentation in themidst of its transition into a 3D presentation. As shown in this figure,the 3D control appears highlighted at this stage to indicate that thenavigation presentation has entered a 3D mode. As mentioned above, thenavigation application generates the 3D view of the navigated map insome embodiments by rendering the map view from a particular position inthe three dimensional scene that can be conceptually thought of as theposition of a virtual camera that is capturing the map view. Thisrendering will be further described below by reference to FIG. 4.

The third stage 315 then illustrates the navigation presentation at theend of its transition into its 3D appearance. As shown by the differencebetween the heights of the buildings in the second and third stages, thetransition from 2D to 3D navigation in some embodiments includes ananimation that shows three dimensional objects in the navigated mapbecoming larger. Generating such animation that shows objectsrising/falling and becoming larger/smaller is further described in aconcurrently filed U.S. patent application Ser. No. 13/632,027, entitled“Displaying 3D Objects in a 3D Map Presentation”.

3. Virtual Camera

The mapping application of some embodiments is capable of displayingnavigation maps from multiple perspectives. The application can showmaps in three dimensions (3D) or in two dimensions (2D). The 3D maps aregenerated simulations of a virtual scene as seen by a virtual camera.When rendering a 3D navigation map, a virtual camera is aconceptualization of the position in the 3D map scene from which thedevice renders a 3D view of the scene. In some embodiments, the mappingapplication renders 3D map view (i.e., 3D map presentations) during mapbrowsing/searching mode, route inspection mode, and/or route navigationmode.

FIG. 4 presents a simplified example to illustrate the concept of avirtual camera 412. In this example, the virtual camera is used togenerate a 3D presentation during a route navigation mode. FIG. 4illustrates a location in a 3D navigation map scene 410 that includesfour objects, which are two buildings and two intersecting roads. Toillustrate the virtual camera concept, this figure illustrates threescenarios, each of which corresponds to a different virtual cameralocation (i.e., a different rendering position) and a differentresulting view that is displayed on the device.

The first stage 401 shows the virtual camera 412 at a first positionpointing downwards at an angle (e.g., a 30 degree angle) towards the 3Dscene 410. By rendering the 3D scene from the position and angle shownin stage 401 the application generates the 3D map view 418. From thisposition, the camera is pointing at a location that is a moving positionin front of the device. The virtual camera 412 is kept behind thecurrent location of the device. “Behind the current location” in thiscase means backward along the navigation application's defined path inthe opposite direction from the current direction that the device ismoving in.

The navigation map view 418 looks as though it was shot by a camera fromabove and behind the device's location indicator 416. The location andangle of the virtual camera places the location indicator 416 near thebottom of the navigation map view 418. This also results in the majorityof the screen being filled with the streets and buildings ahead of thepresent location of the device. In contrast, in some embodiments, thelocation indicator 416 is in the center of the screen, with half of thescreen representing things ahead of the device and the other halfrepresenting things behind the device. To simplify the figure, no roadsigns are depicted for the views 418, 428, and 438.

The second stage 402 shows the virtual camera 412 at a differentposition, pointing downwards towards the scene 410 at a larger secondangle (e.g., −45°). The application renders the scene 410 from thisangle, resulting in the 3D navigation map view 428. The buildings andthe roads are smaller than their illustration in the first navigationmap view 418. Once again the virtual camera 412 is above and behind thelocation indicator 416 in the scene 410. This again results in thelocation indicator appearing in the lower part of the 3D map view 428.The location and orientation of the camera also results again in themajority of the screen displaying things ahead of the location indicator416 (i.e., the location of the car carrying the device), which is whatsomeone navigating needs to know.

The third stage 403 shows the virtual camera 412 at a top-down view thatlooks downwards on a location in the 3D map scene 410 that was used torender the 3D views 418 and 428. The scene that is rendered from thisperspective is the 2D map view 438. Unlike the 3D rendering operationsof the first and second stages that in some embodiments are perspective3D rendering operations, the rendering operation in the third stage isrelatively simple as it only needs to crop a portion of the 2D map thatis identified by a zoom level specified by the application or the user.Accordingly, the virtual camera characterization in this situationsomewhat unnecessarily complicates the description of the operation ofthe application as cropping a portion of a 2D map is not a perspectiverendering operation.

In some embodiments, the virtual camera can be made to move by changingthe zoom level for viewing the map after the map enters a 3D mode, asfurther described below. In some of these embodiments, the applicationswitches to a top-down mode (where the rendering position faces straightdown) that produces 2D views when the zoom level reaches a particularzoom out level.

At the third stage 403, the mapping application in some embodimentsswitches from rendering a 3D scene from a particular perspectivedirection to cropping a 2D scene when the camera switches from the 3Dperspective view to a 2D top-down view. This is because in theseembodiments, the application is designed to use a simplified renderingoperation that is easier and that does not generate unnecessaryperspective artifacts. In other embodiments, however, the mappingapplication uses a perspective rendering operation to render a 3D scenefrom a top-down virtual camera position. In these embodiments, the 2Dmap view that is generated is somewhat different than the map view 438illustrated in the third stage 403, because any object that is away fromthe center of the view is distorted, with the distortions being greaterthe further the object's distance from the center of the view.

The virtual camera 412 moves along different trajectories in differentembodiments. Two such trajectories 450 and 455 are illustrated in FIG.4. In both these trajectories, the camera moves in an arc and rotatesdownward as the camera moves upward along the arc. The trajectory 455differs from the trajectory 450 in that in the trajectory 455 the cameramoves backward from the current location as it moves up the arc.

While moving along one of the arcs, the camera rotates to maintain apoint ahead of the location indicator at the focal point of the camera.In some embodiments, the user can turn off the three dimensional viewand go with a purely two dimensional view. For example, the applicationof some embodiments allows a three dimensional mode to be turned on andoff by use of a 3D button 460. The 3D button 460 is essential to theturn-by-turn navigation feature, where it has a role as an indicator anda toggle. When 3D is turned off, the camera will maintain a 2Dnavigation experience, but when 3D is turned on, there may still be sometop-down perspectives when 3D viewing angles are not appropriate (e.g.,when going around a corner that would be obstructed in 3D mode).

Although FIG. 4 illustrates the use of the virtual camera to render a 3Dnavigation presentation, one of ordinary skill will realize that thevirtual camera can also be used to render a 3D presentation of a 3Dscene during map browsing/searching mode or route inspection mode. Inthese modes, the position of the device maybe indicated in some cases,but the 3D scene typically does not include lines trailing and leadingthis position to indicate the direction of the device's past movementand expected future movement. The scene instead will include objects inthe 3D map scene that should be rendered to provide a 3D mappresentation for map browsing, map searching, and/or route inspection.

B. Representing Traffic

As mentioned above, the mapping application employs several noveltechniques for representing and highlighting traffic on routes. FIG.5-FIG. 9B illustrate some of these novel techniques. FIG. 5 illustrateshow some embodiments turn on the traffic services and display trafficdata on a map view of the integrated mapping application of someembodiments of the invention. This figure shows six stages 505, 510,515, 520, 525, 530 of interaction with the mapping application. Thefirst stage 505 shows a map view 535 of the mapping application thatshows a current location 540 of the device.

The second stage 510 shows the device after the map view of the mappingapplication has been replaced by a view 545 presented by the operatingsystem of the device. In some embodiments, the user can change to the OSview 545 from the map view 535 by pressing one of the buttons (notshown) of the device. In the OS view 545, the device displays severalicons of several applications in a dock area 552 and on a page of theUI. One of the icons on this page is an icon 550 for the mappingapplication. Another icon is an icon 555 for reviewing and editing thesettings of the device. The second stage 510 shows the user's selectionof the icon 555 by touching the location that this icon is displayed onthe touch-sensitive screen of the device.

The third stage 515 shows the device after the settings page 560 hasbeen opened in response to the user's selection of the settings icon555. It also shows the user's selection of the location services option565 on this page. In response to this selection, the device opens alocation services page 570, as shown in the fourth stage 520. In thefourth stage, several location services are listed for severalapplications and for the operating system. Also listed is a systemservices option 575, which is selected in the fourth stage.

The fifth stage 525 then shows the opening of a system services page580, which lists one or more system services, including a trafficservice 585. This stage shows the selection of this service to turn ontraffic reporting, which now allows one or more traffic harvestingservices (that are communicatively coupled to the device directly orindirectly through other servers) to collect data from the device toidentify traffic congestion in the localities traversed by the device.U.S. patent application Ser. No. 13/610,807, entitled “HarvestingTraffic Information from Mobile Device,” describes the harvesting ofsuch data in more detail, and is incorporated herein by reference. Insome embodiments, the servers that gather the traffic data from themobile devices that have turned on traffic reporting, also collecttraffic data from one or more other sources that provide traffic data.As further described below, these servers then generate traffic tiles,distribute these tiles to the mobile devices (directly or indirectlythrough other servers), periodically and dynamically update these tiles,and re-distribute these tiles to the mobile devices.

The sixth stage 530 shows the device after it has returned to a map view590 of the mapping application. In some embodiments, the device returnsto this view when the user exits the system services page 580 bypressing a button (not shown) of the device, and then selecting the mapicon 550 on the page 545 of the UI.

The map view 590 that is shown in the sixth stage illustrates trafficabout two intersecting highways. The map view 590 uses a particularscheme for displaying traffic data. This scheme uses (1) dashed lines ofa first color 592 (e.g., red) to represent heavy traffic congestion, (2)dashed lines of a second color 594 (e.g., orange) to represent moderatetraffic congestion, and (3) no lines or other indicators to representthe lack of traffic along a road. Also, in this scheme, the dashed linesthat represent heavy or moderate traffic congestion are illustrated nextto the portions of the roads that have such congestion. For instance, inmap view 590, one portion along north bound I-5 has heavy congestion asindicated by dashed lines 592, while one portion on east bound I-10 hasmoderate congestion as indicated by dashed lines 594.

FIG. 6 illustrates another way that some embodiments use to turn on thetraffic services and display traffic data on a map view of theintegrated mapping application of some embodiments of the invention.Under this approach, traffic data is not necessarily shown when thetraffic services are enabled through system services, but rather need tobe actively requested through selection of a traffic button in the mapview. This figure shows four stages 605, 610, 615, and 620 ofinteraction with the mapping application. The first stage 605 shows amap view 535 of the mapping application that shows a current location540 of the device. This stage also shows the selection of the page curlicon 625.

The second stage 610 shows the user's dragging of the page curl icon 625to expose the secondary UI screen 630. In some embodiments, the touchselection of the page curl icon 625 peels back the map view 535 toexpose the screen 630; no drag operation is needed in these embodimentsto peel back the page curl.

As shown in the second stage 610, the secondary UI screen 630 includes ashow traffic button 635. The third stage 615 shows the selection of thisbutton 635. The fourth stage 620 shows a map view 690 that is similar tothe map view 590 of FIG. 5, except that in the map view 690 the dashedtraffic lines are shown in the middle of the highways not adjacent tothem. Specifically, the map view 690 uses the same color and patterningscheme as the map view 590 as it uses (1) dashed lines of a first color692 (e.g., red) to represent heavy traffic congestion, (2) dashed linesof a second color 694 (e.g., orange) to represent moderate trafficcongestion, and (3) no lines or other indicators to represent the lackof traffic along a road. Also, in this scheme, the dashed lines thatrepresent heavy or moderate traffic congestion overlay the portions ofthe roads that have such congestion. For instance, in map view 690, oneportion along north bound I-5 has heavy congestion as indicated bydashed lines 692 that overlay this direction, while one portion on eastbound I-10 has moderate congestion as indicated by overlaid dashed lines694. As further described below by reference to FIG. 8B, the mappingapplication of some embodiments for certain zoom levels of the map drawsthe traffic patterns over the roads, while for other zoom levels drawsthe traffic patterns adjacent to the roads. This is because the mappingapplication of some embodiments draws the traffic patterns over theroads when the roads are sufficiently large (after a particular zoomlevel) so as not to be occluded by the traffic patterns.

It should be noted that in some embodiments, the mapping application canshow the traffic data in the map view 690 only if the traffic service585 was previously enabled before the traffic button 635 was selected.In other words, some embodiments show traffic data only when the devicehas its traffic service 585 turned on and the user has requested theshowing of traffic data through the show traffic button 635. In otherembodiments, however, the device does not require any separateenablement of the traffic service, and instead simply shows the trafficdata upon the selection of the traffic button 635. Also, in someembodiments, the traffic service 585 is turned on by default in order toreport traffic data when the user first starts to use the device or whenthe device is turned on (i.e., each time the device goes through apower-on, boot-up cycle). In these embodiments, the traffic service 585would have to be turned off to opt out the device from reporting thetraffic data.

FIG. 7 illustrates yet another way that some embodiments use to turn onthe traffic services. Under this approach, traffic data again is notnecessarily shown when the traffic services are enabled through systemservices, but rather need to be actively requested through selection ofa traffic button in the map view. In this example, the traffic buttonthat is used to request the traffic data is a floating button 720 thatis illustrated in a first stage 705 of FIG. 7.

The second stage 710 of this figure shows the selection of this button.The third stage then shows this button as being selected (through thehighlighting of this button) and shows the map view 790, which isidentical to the map view 590 that was described above by reference tothe sixth stage 530 of FIG. 5. Again, in some embodiments, the mappingapplication can show the traffic data in the map view 790 of FIG. 7 onlyif the traffic service 585 was previously enabled before the trafficbutton 720 was selected. In other embodiments, however, the device doesnot require any separate enablement of the traffic service, and insteadsimply shows the traffic data upon the selection of the traffic button720.

The traffic data that is shown is highly useful in allowing a user toidentify a route to avoid traffic. In some embodiments, a user canidentify such a route in one of several ways. Two such ways are throughthe browsing of the map view that illustrates the traffic data, and theinspection of alternative routes that are displayed on the map view.

FIG. 8A illustrates an example of the user browsing an area about themap view 590 that was described by reference to FIG. 5. This browsing isillustrated in terms of four stages of operation 805-820. The firststage 805 shows the map view 590 after traffic data has been presentedfor this view. In this view, the I405N is shown to have traffic in thenorth bound direction at its intersection with the I10 freeway. Thesecond stage 810 and the third stage 815 show the user browsing aboutthis view by performing a swipe operation through a single finger dragoperation. The fourth stage 820 illustrates another portion 850 of themap that shows the northbound I5 freeway not having any congestion.Hence, the user may choose to travel along the I5 freeway to avoid thecongestion around the I405 freeway.

FIG. 8B illustrates another example of the user browsing a mapping toview traffic data. In this example, the user changes zoom levels to viewmap data about a certain location. The user can do this in order to geta better sense of the traffic around a particular location. Thisbrowsing is illustrated in three stages. The first stage 855 shows afirst view 870 of a map at a first zoom level. In this view, twodifferent traffic congestion patterns 857 and 859 are shown for heavy tomoderate traffic on a particular road 861. At this zoom level, themapping application has overlaid the traffic patterns on top of the road861, as for instance it might have determined that the roads aresufficiently large (e.g., sufficiently wide) for the application tooverlay the traffic patterns over the roads without occluding the roads.

In the second stage 860, the user performs a zoom out operation to zoomout of the current map view. In some embodiments, zooming out changesthe zoom level from a higher value to a lower value, but otherembodiments may specify the zoom level by using the opposite designation(i.e., by having the high zoom levels correspond to further views of themap). Also, in this example, the zoom out operation is performed througha multi-touch pinch operation, although it can be done through otheroperations in other embodiments.

After the zoom out operation of the second stage 860, the third stage865 shows a second view 880 of the map at a second zoom level. In thisview, again two different traffic congestion patterns 857 and 859 areshown for heavy to moderate traffic on the particular road 861 and anearby road 863. At this zoom level, the mapping application has drawnthe traffic patterns adjacent to roads 861 and 863, as for instance itmight have determined that the roads are too small (e.g., too narrow)for the application to overlay the traffic patterns over the roadswithout occluding the roads.

FIG. 9A illustrates an example of the user inspecting alternative routesthat are displayed on the map view to identify the least congestedroute. This figure illustrates this example in terms of four stages905-920. The first stage 905 illustrates the map view 590 that isdisplayed in the sixth stage 530 of FIG. 5. This stage shows thecongestion along various portions of two freeways, with one of theportions that has heavy traffic being a portion of the 1405N freeway.This stage also shows the user selection of the direction control 260.

The second stage 910 illustrates the direction entry page 980 after theuser has entered the starting address and partially completed the endingfield. This page also shows the selection of a recent direction that wasauto-populated in the table 282 after the partial data provided by theuser in the ending field.

The third stage 915 then shows two routes 950 and 955 that are presentedto the user. Both routes 950 and 955 are highlighted but the first routeappears with a brighter and/or more saturated color. The first routetraverses along a congested portion of the I405N. This route is defaultselected as indicated by the highlighting of this route's name in thethird stage. The third stage also shows that the traffic indicatingfirst color pattern 592 appears brighter and/or more saturated in thisstage than it did in the first stage 905. In some embodiments, themapping application brightens and/or saturates the color, changes thecolor, or otherwise changes the appearance of the traffic indicatingpatterns when they are (1) under the identified path of a displayedroute, (2) are near such an identified path, or (3) are near such anidentified path and are for the same direction as the identified path.The scheme illustrated in FIG. 9A brightens and/or saturates the colorof traffic indicating patterns that are under the identified path of adisplayed route (e.g., because of the zoom level) or are near such anidentified path and are for the same direction of traffic as theidentified path. This scheme does not change the appearance of thetraffic indicating patterns that are near the identified path but arenot for the same direction of traffic as the identified path. Hence, inthis example, the patterned traffic lines along the south bounddirection of 1405 are not brightened or otherwise modified in the thirdstage 915.

The third stage also illustrates the user's selection of the secondroute by touching the banner that lists this route's name. The fourthstage 920 then shows the highlighting of the second route 955. Thisstage still highlights the first route 950 but it does so with a lessbright and/or less saturated color than is used for highlighting thesecond route 955. Once the first route is de-emphasized and the secondroute is emphasized, the patterned traffic lines 592 return to theirappearance in the first stage 905 as they are no longer along a portionof a selected route. As shown in the fourth stage, the second route 955does not have congestion in the northbound direction. Hence, the usercan select this route to avoid congestion between the start and endlocations.

As mentioned above, the mapping application changes the appearance ofthe traffic indicating patterns when they are (1) under the identifiedpath of a displayed route, (2) are near such an identified path, or (3)are near such an identified path and are for the same direction as theidentified path. In the example illustrated in FIG. 9A, the mappingapplication brightens and/or saturates the color appearance of thetraffic patterns underneath the displayed route or near the displayedroute in the same direction as this route. However, other embodimentsmay change the appearance of the traffic patterns differently. Forinstance, some embodiments might darken and/or reduce the saturation ofthe traffic patterns underneath the displayed route or near thedisplayed route in the same direction as this route, as illustrated inFIG. 9B. FIG. 9A pictorially shows the brightening and/or saturation ofthe traffic patterns in terms of line markers in the 45 and 135 degreedirections in the third stage 915, while FIG. 9B pictorially shows thedarkening and/or de-saturation of the traffic patterns in terms of linemarkers in the −45 and −135 degree directions in the third stage 925.

C. Representing Other Traffic Conditions

The mapping application of some embodiments provides other traffic androad information when its traffic reporting feature has been turned on.FIG. 10A illustrates an example of one such other information. Thisfigure illustrates in four stages 1002-1008 how the mapping applicationreports roadwork along a road. As shown in the first stage, theapplication in some embodiments specifies roadwork at a particularlocation in the world by providing at the corresponding location on themap view an icon that has a picture of a working man.

This icon 1010 is a selectable item in the UI. The second stage shows auser selecting the icon by touching the location on the screen thatdisplays the icon. The third stage 1006 then shows that the selection ofthe icon results in a banner 1012, which has a label for the icon (herereading “Road Work”), a picture for the icon (here again showing aworking man) and an arrow to the right to indicate additionalinformation. Other embodiments will use other representations for thelabel, picture and info components of the banner.

The third stage 1006 shows the selection of the banner's arrow. Thefourth stage 1008 shows that this selection results in a new displayedwindow that provides additional information regarding the roadwork. Inthis case, the additional information provides the start date for theroadwork and some other description for this roadwork.

In some embodiments, the mapping application provides a new windowdisplay to provide the additional information in the fourth stage 1008when the device's screen is too small to display all the informationregarding the roadwork in a popover window. However, when the device'sscreen is large enough or has sufficient resolution to accommodate apopover window that can be displayed over the window displaying the mapview and that can provide sufficient information, the mappingapplication in some embodiments provides this popover window. FIG. 10Billustrates one such popover window. This figure illustrates the sameexample as illustrated in FIG. 10A, except in FIG. 10B the device has alarger screen than the device illustrated in FIG. 10A. As the screen islarger, the fourth stage 1028 in FIG. 10B shows the opening of a popoverwindow 1034 to provide the additional information about the road workafter the user selects the info arrow in the banner 1032 in the thirdstage 1026.

The mapping application of some embodiments similarly provides trafficinformation for other types of traffic or road conditions. FIGS. 10C-10Epresent examples of other traffic or road conditions that are handled ina similar fashion to the roadwork example illustrated in FIG. 10A. FIG.10C-10E respectively illustrates how the mapping application of someembodiments shows ramp closings, hazardous conditions and accidentsalong a map. These figures show that this application illustrates thesethree types of conditions in terms of three different icons 1040, 1042,and 1044. In four stages, each of these figures shows that selection ofan icon opens a banner 1046, 1048, or 1050 that provides someinformation about each condition. In these stages, these figures alsoshow that the selection of the arrow on each banner opens another windowthat provides additional information about the ramp closing, hazardouscondition or accident. As in the example illustrated in FIG. 10B, themapping application in some embodiments provides a popover window(similar to window 1034) to provide additional information about theramp closing, hazardous condition, or accident specified by the banner1046, 1048, or 1050 when the device has a large enough screen or highenough resolution to accommodate a sufficiently sized popover window toshow useful data.

D. Drawing Traffic Representations in Perspective 3D View

As mentioned above and as further described below, the mappingapplication of some embodiments draws representations of trafficcongestion (e.g., the patterned traffic lines shown in FIGS. 5-9B) ortraffic conditions over or along roads that it draws. The drawings ofthe traffic representations and the roads are part of the same renderingprocess, which allows the traffic representations to be drawn in accordwith the rendering of the roads and other objects in the 2D or 3D scene.Hence, the traffic representations do not unnecessarily occlude otherobjects in the 2D or 3D map view.

To better illustrate the rendering of the traffic representations inharmony with the road rendering, FIGS. 10F and 10G illustrateperspective 3D views of map locations that have traffic congestion, andin the case of FIG. 10F, traffic conditions. In these examples, thetraffic representations are rendered just like any other object in the3D scene and hence appear seamlessly and unobtrusively within the scene.In other words, their positions and orientations are defined like anyother object in the 3D scene, and then the scene (which includes thetraffic representations, roads, and possibly other objects) is renderedfrom the view of a virtual camera viewing the scene.

FIG. 10F illustrates a 3D perspective view of the map that isillustrated in three stages 1052, 1054 and 1056. The first stage 1052presents the initial perspective view that includes traffic pattern1058, ramp closed icon 1060 and construction icon 1062. As there are no3D objects in this 3D scene that occlude the view of the virtual camerathat defines the position and orientation of the perspective view, thetraffic pattern 1058 and the icons 1060 and 1062 are fully visible andnot occluded by any other objects in the 3D scene.

In the perspective view illustrated in the first stage 1052, the trafficpattern has been rendered to overlap and fit within a road. Both thetraffic pattern and this road have been rendering by using a perspectivetransform as both the traffic pattern and the road appear to be thinnertowards the top 1064 of the road. The perspective operation also hasmade the traffic pattern denser towards the top 1064 of the road. Also,in this perspective view, the icons 1060 and 1062 appear as verticallystanding objects in the 3D scene.

The second stage 1054 then illustrates the map presentation after theramp-closed icon has been selected. In response to this selection, abanner 1066 has been opened to provide more information about theclosing of the ramp. The third stage 1056 next illustrates the mappresentation after the roadwork icon 1062 has been selected. In responseto this selection, a banner 1068 has been opened to provide moreinformation about the roadwork. In some embodiments, these banners alsoappear as vertically standing objects in the 3D scene being rendered.

FIG. 10G presents another example of rendering traffic representationsin order to further illustrate how the mapping application treatstraffic representations as just another object in a 3D scene that itrenders. To illustrate this point, this example shows a traffic patternthat does not occlude other objects in the 3D scene, but instead isgetting partially occluded by other objects in the 3D scene because itis partially behind these objects.

This example is illustrated in four stages 1070, 1072, 1074 and 1076.The first stage 1070 shows a 2D view of a map of a location in SanFrancisco that has traffic congestion 1078 along a particular road. Thesecond stage 1072 shows the same location but now in a 3D perspectiveview, as indicated by the highlighting of the 3D button 1080.

The third stage 1074 shows another 3D perspective view of this locationafter the mapping application has zoomed into that location (e.g., inresponse to user input). As shown in this stage, this zooming hasresulted in the display of buildings that appear as 3D objects in the 3Dscene being rendered. In this 3D scene, two of the 3D buildings 1082 and1084 occlude portions of the traffic pattern 1078 as these two buildingsare between the position of the virtual camera rendering the scene andthose portions of the traffic pattern.

The fourth stage 1076 then shows the map location after it has beenrotated clockwise. In this rotated view, other portions of the trafficpattern 1078 are occluded by two other buildings 1086 and 1088. Again,these occluding buildings occlude portions of the traffic pattern asthey are between the position of the virtual camera and these portions.The third and fourth stages 1074 and 1076 together illustrate that thetraffic pattern 1078 (like other traffic representations) is simply anobject in the 3D scene for which the mapping application initiallyidentifies its location and then renders along with other objects in thescene based on the vantage point of the virtual camera.

After generating the traffic pattern 1078 representation, the mappingapplication's rendering module renders the composite scene by arrangingthis representation in the scene with other objects in the scene basedon the layer information of this representation and of other objects inthe scene. In some embodiments, this layer information is derived fromthe perspective view of the virtual camera. Accordingly, because of thislayering, different buildings in the third stage 1074 and fourth stage1076 occlude different parts of the rendered traffic pattern as they arebetween the virtual camera view and the occluded parts of the renderedtraffic.

II. Data Structure and its Use in Rendering Traffic Data

A. Dynamic Road Condition Objects and Linking Objects

Some embodiments of the invention use several different novel datastructures to express traffic data and associate this data with roaddata. FIG. 11A conceptually illustrates one such data structure 1100.Specifically, this figure illustrates using a linking object layer 1140to map dynamic road-condition data 1110 to static road map 1130. Oneexample of road-condition data includes traffic data. In someembodiments, the traffic data includes data that pertains to the speedof traffic along the roads, while in other embodiments this dataincludes data relating to occurrence of accidents along the roads. Also,road-condition data includes other types of data, such as weatherconditions (e.g., rain, snow, etc.) or surface road conditions (e.g.,ice on the road, wet conditions, construction, rough road conditions,etc.).

As shown FIG. 11A, linking object layer 1140 is one of three layers ofobjects, with the other layers being the static road object layer 1150and the dynamic road-condition object layer 1160. These three layersrespectively include several linking objects 1120, static road objects1130 and dynamic road-condition objects 1110. Collectively, these threelayers describe a road with several segments and the differentconditions along different segments of the road.

In some embodiments, the static road objects 1130 are road vector tilesthat store road geometry information for a given geographic area (e.g.,for a given section of a map) in terms of vector data. This vectorgeometry information is used to render the traffic map. The informationcontained in the static road object 1130 is static, which means once itis downloaded to the device, it will not need to be downloaded orupdated for a while. Of course, if the device has to delete this objectfrom its memory, it will have to be downloaded again. Also, in someembodiments, the server that generates the static road tiles, updatessuch tiles once in a while so that it can support a new version of themap or a new version of its services. At such occasions, the devicewould have to receive new static road tiles for the areas that itsmapping application needs to display.

In some embodiments, the dynamic road condition objects 1110 are tilesgenerated by a set of servers that monitor and generate data regardingroad conditions. In some embodiments, this set of servers does notinclude any server used to generate the road tiles, while in otherembodiments the set of servers is the same server set or includes one ormore of the servers that generate the road tiles.

In some embodiments, a dynamic road condition object 1110 contains roadcondition data such as traffic congestion, detours, and trafficaccidents for certain sections of roads. As mentioned above, the roadcondition data in some embodiments also includes other information suchas weather conditions (e.g., rain, snow, etc.) and surface roadconditions (e.g., ice on the road, wet conditions, construction, roughroad conditions, etc.).

The information contained in the dynamic road condition object isdynamic as it gets updated periodically and/or in real-time by a set ofservers that provides the dynamic road condition data. This informationis relayed through a network (e.g., a cellular wireless network) that insome embodiments is the same network that transmits the static roaddata, other mapping data, the route data and/or the navigation data. Inother embodiments, the dynamic road condition data is provided through adifferent network than the network that provides the static road data,other mapping data, the route data and/or the navigation data.

The dynamic road condition objects 1110 need to be mapped to physicallocations on a map in order to render the traffic map. In someembodiments, each dynamic road condition object is associated with onestatic road object through a linking object 1120, as shown in FIG. 11A.However, as further described below, each dynamic road condition objectin some embodiments is associated with more than one static road object,or one static road object is associated with more than one dynamic roadcondition object.

Irrespective of whether there is a one-to-one association between adynamic road condition object and a static road object, or a one-to-manyor many-to-one association between these objects, some embodiments stilluse one linking object to establish each association between a dynamicroad condition object and a static road object. The linking object 1120establishes the link between a dynamic road condition object 1110 and astatic road object 1130. As further described below, the linking object1120 contains the data that allows one dynamic road condition object tolink to one static road object. Also, as further described below, thelinking object in some embodiments contains other positional datanecessary for rendering the road condition data in a dynamic roadcondition object over or about the roads defined in the static roadobject. By providing such positional data, the linking object simplifiesthe process of rendering the road condition data (e.g., the trafficdata), and ensures that such renderings are at the desired locationsover or adjacent to the roads.

In some embodiments, the linking object 1120 is an object that isinstantiated from a class that defines the attributes (and in somecases, the functions) associated with the linking object. In otherembodiments, the linking object 1120 is a conceptual representation ofanother construct (e.g., a reference, a pointer, a common index valueetc.) that is used to define an association between a dynamic roadcondition object and a static road object.

The linking object layer 1140 acts as a translation layer between thedynamic road condition object layer 1160 and the static road objectlayer 1150. Because of the linking object layer 1140, a single versionof dynamic road condition objects 1110 can be mapped to multipleversions of static road objects that are provided at different times(e.g., for multiple different versions of a mapping application).Consequently, the traffic server only needs to provide one version oftraffic tile to support multiple versions of road tiles and mappingapplications that might be deployed at any given time on devices thatare subscribers or recipients of the mapping, navigation and/or trafficservices.

B. Linking Traffic Objects

FIG. 11B illustrates a more detailed example of a data structure 1155that is used to represent a road and the traffic associated withdifferent segments of the road. The data structure 1155 is the same asthe data structure 1100 of FIG. 11A in that it has a static road objectlayer 1150, a linking object layer 1185, and a dynamic road-conditionobject layer 1175. Also, the static road objects 1130 in FIGS. 11A and11B are identical.

However, there are two differences between these two structures thatshould be noted. First, the dynamic object layer 1175 includes dynamictraffic objects 1170 that dynamically receive and store traffic data,which is a specific type of road condition data. As mentioned above,traffic data in some embodiments includes data that pertains to thespeed of traffic along the roads, while in other embodiments this dataalso includes data relating to the occurrence of accidents along theroads.

Second, the linking object layer 1185 includes linking traffic objects(LTO) 1180 that not only establish each association between a dynamictraffic object 1170 and a static road object 1130, but also store thepositional data necessary for rendering the traffic data in a dynamictraffic object over or about the roads defined in the static roadobject. By providing such positional data, the linking object simplifiesthe process of rendering the traffic data, and ensures that suchrenderings are at the desired locations over or adjacent to the roads.One example of such a linking traffic object and the positional datathat it stores will be described below by reference to FIG. 14. Asfurther described below, FIG. 14 also illustrates an example of adynamic traffic object 1170.

In the discussion below regarding FIGS. 12-17, the dynamic roadcondition that is described is dynamic traffic data. This discussion,however, is equally applicable to any other dynamic road conditions,such as weather conditions and road surface conditions.

FIG. 12 provides a conceptual illustration of how the data in a dynamictraffic object 1170 and its associated linking traffic object 1180provide the data necessary for rendering the traffic for a particularroad segment or set of road segments. This figure illustrates therendering pipeline of the mapping application of some embodiments. Asshown in this figure, the rendering pipeline 1200 includes a networkinterface 1202, a map processor 1205, a traffic updater 1210, a datastorage 1215, one or more mesh builders 1220, one or more mesh buildingprocessors 1225, a traffic tile provider 1230, a road tile provider1240, one or more other tile providers 1245, a controller 1250, avirtual camera 1260, and a rendering engine 1270.

The storage 1215 stores the road description 1155 that was describedabove by reference to FIG. 11B. This road data structure 1155 includesseveral different layers of data structure that are populated by the mapprocessor 1205 and the traffic updater 1210 based on data that these twomodules receive through the network interface 1202. The networkinterface 1202 is the interface between the device and a network 1206through which the device receives road data and updated traffic datafrom a set of servers 1204, which as mentioned before include one subsetof servers for sending road data and another subset of servers forsending traffic data.

The map processor receives and processes road objects (e.g., road tiles)1130 and their associated linking traffic objects 1180 in someembodiments. In some embodiments, the map processor receives theseobjects each time it has to receive a new road or a new road segmentthat it has not previously received, or it has previously received butit has since removed from the storage 1215. The map processor 1205 alsoreceives new road objects 1130 and their associated linking objects 1180each time a new version of a map or a new version of the mappingapplication is released.

The traffic updater 1210 receives and processes traffic data through thenetwork interface 1202, and stores this data in dynamic traffic objects1170 of the road description 1155. In some embodiments, the trafficupdater also creates (e.g., instantiates) the traffic objects, while inother embodiments, the traffic updater simply receives traffic objects(e.g., traffic tiles) that it or the map processor associates with thestatic road objects through the linking objects. In yet otherembodiments, the traffic updater modifies the traffic objects (e.g., thetraffic tiles) that it receives. The traffic updater also periodicallyand/or in real time receives and/or updates the dynamic traffic objects.In some embodiments, the map processor 1205 and traffic updaters 1210include tile retrievers/downloaders and decompressors as described inU.S. Provisional Patent Application 61/699,862, entitled “Generating MapData for Rendering,” and as further described in U.S. Non-Provisionalpatent application Ser. No. 13/631,998, entitled “Generation of RoadData,” filed concurrently with this application. The ProvisionalApplication 61/699,862, and the concurrently filed non-provisionalapplication are incorporated herein by reference.

As mentioned above, traffic tile generating servers in some embodimentsgather traffic data from the mobile devices that have turned on trafficreporting, and collect traffic data from one or more other sources thatprovide traffic data. These servers then generate traffic tiles,distribute these tiles to the traffic updaters of the mobile devices(directly or indirectly through other servers), periodically anddynamically update these tiles, and re-distribute these tiles to thetraffic updaters of the mobile devices.

To generate the traffic tiles, the servers and/or traffic updaters (1)identify several or numerous sets of traffic segments for several ornumerous roads, (2) identify different groupings of the traffic segmentsets, and (3) for each group of traffic segment sets, define a traffictile that includes data that specifies the traffic segments of the groupand the traffic congestion along the traffic segments of the group. Asdescribed above and below, each traffic tile specifies trafficcongestion data for each traffic segment based on the traffic datagathered from one or more sources that provide data regarding trafficalong the roads.

The downloaded road, traffic and other tiles are used to render theroads and other map data along with the traffic data. The controller1250 directs much of the processes for performing this rendering. Fromthe virtual camera 1260, the controller receives the portion of the mapthat is currently being requested for display. Based on the identifiedportion of the map and in some embodiments areas surrounding thisportion, the controller directs the tile providers 1230, 1240 and 1245to retrieve view tiles for it to pass along to the rendering engine 1270to render. In some embodiments, the view tiles include road tiles,traffic tiles, and building tiles that describe respectively roads in ascene, the traffic along the roads in the scene, and the buildings inthe scene.

The tile providers 1230, 1240 and 1245 instantiate and direct the meshbuilders 1220 (also referred to as tile sources) to build differentlayers of view tiles. Depending on the type of map being displayed bythe mapping application, a tile provider may instantiate differentnumbers and different types of mesh builders. For example, for a 2D or3D rendered vector map (i.e., a non-satellite image map), someembodiments instantiate separate mesh builders to build meshes forlandcover polygon data (e.g., parks, bodies of water, etc.), roads,place of interest markers, point labels (e.g., labels for parks, etc.),road labels, buildings, raster data (for certain objects at certain zoomlevels), as well as other layers of data to incorporate into the map.One of the mesh builders 1220 builds a mesh that specifies trafficmarkers (e.g., traffic patterns shown in FIGS. 5-9B) along the roads. Insome embodiments, each of the tile providers 1230, 1240, and 1245instantiates its own set of mesh builders 1220.

The tile providers receive from the controller a particular view (i.e.,a volume, or viewing frustrum) that represents the map view to bedisplayed (i.e., the volume visible from the virtual camera). The tileproviders perform any culling (e.g., identifying the surface area to bedisplayed in the virtual map tile) in some embodiments, then send the“empty” view tiles to the mesh builders, which then have to performtheir operations and return “built” view tiles back to the tileproviders. Each view tile indicates an area of the world for which amesh builder has to draw a mesh. Upon receiving such a view tile, a meshbuilder identifies the map tiles (e.g., a road tile, a traffic tile,etc.) that it needs and directs a tile processor (not shown) to retrievethese tiles from the data storage 1215 or from the mapping servers 1204.

Upon receiving the tiles back from the tile processor, the mesh builderuses vector data stored in the tiles to build a polygon mesh for thearea described by the view tile. In some embodiments, the mesh builderuses several different mesh building processors to build the mesh.Examples of these processors include a mesh generator, a triangulator, ashadow generator, a texture decoder, etc. In some embodiments, theseprocessors (and additional mesh building functions) are available toeach mesh builder, with different mesh builders using differentfunctions.

One of the mesh builders in some embodiments builds a mesh with trafficpatterns. This mesh builder identifies one or more segments of the roadthat need to be rendered for display by the device from the view tilesthat it receives. For each road segment that this mesh builderidentifies for rendering, the builder identifies its correspondingtraffic segments and receives the static road tiles 1130, the linkingtraffic tiles (e.g., linking traffic object(s) 1180), and the dynamictraffic tiles (e.g., the dynamic traffic object 1170) for these road andtraffic segments.

Based on these received road, linking and traffic tiles, the trafficmesh builder identifies the portions of the traffic segments that needto be rendered with a particular traffic pattern that is in a particularcolor, and then uses the mesh building processors 1225 to generate thedesired traffic patterns with the desired colors. As mentioned above,the mapping application of some embodiments draws traffic congestion onthe map as a patterned set of lines with different colors to indicatedifferent traffic conditions. In order to do that, the mesh builderdirects the mesh building processors to produce different sets ofpolygons that are differently colored for different regions on or alonga road that have different levels of traffic congestion.

Each mesh builder returns the view tiles that it builds to itscorresponding tile provider. In some embodiments, the tile providerperforms culling on the built mesh using the particular view from thevirtual camera (e.g., removing surface area too far away, removingobjects that will be entirely behind other objects, etc.). In someembodiments, the tile provider receives the built view tiles from thedifferent mesh builders at different times (e.g., due to differentprocessing times to complete more and less complicated meshes, differenttime elapsed before receiving the necessary map tiles from the tileprocessor, etc.). Once all of the layers of view tiles have beenreturned, the tile provider of some embodiments puts the layers togetherand releases the data to the controller for rendering. Accordingly, insome embodiments, the traffic tile provider provides traffic view tilesto the controller while the road tile provider provides road view tilesto the controller. Other embodiments may have one tile provider for roadand traffic data. In these embodiments, this tile provider receives thetraffic and road data from one or more mesh builders, combines this datainto one tile (when it receives the traffic and road data from two ormore mesh builders), and provides a view tile that includes traffic androad data for rendering.

The controller then combines the view tiles that relate to the sameregion of the map view and passes these tiles to the rendering engine1270 for rendering. For instance, in the embodiments that the controllerreceives traffic view tiles and road view tiles from different tileproviders, the controller combines these view tiles (also called virtualtiles above and below) and provides these combined tiles to therendering engine to render. In some embodiments, the combined view tilesaccount for the arrangement of the objects in the rendered scene basedon the layer information of the objects in the scene. These objectsinclude the roads and traffic representations as well as any otherobjects (e.g., buildings) that may occlude these representations basedon a particular view of the virtual camera. In some embodiments, thecombined view tiles specify layer information for the trafficrepresentation that allows the rendering engine 1270 to determine whichportions of the traffic representation are occluded by other objects inthe scene for the particular view of the virtual camera.

Accordingly, based on the tiles that it receives from the controller,the rendering engine 1270 generates a rendered section 1235 of a mapthat shows traffic data (if any) along the roads (if any) that are inthat section of the map. The above-incorporated U.S. Provisional PatentApplication 61/699,862 and U.S. Non-Provisional Application entitled“Generation of Road Data,” further describe the operation of therendering engine 1270, virtual camera 1260, controller 1250, tileproviders 1230, 1240, and 1245, mesh builders 1220, mesh buildingprocessors 1225, and the interface to the servers 1204.

The approach described above can be used to generate the description oftraffic congestion representations or traffic sign representations, suchas those shown in FIGS. 10A-10G. In some embodiments, the only differentbetween the generation of the description of the congestion and signrepresentations is that for the sign representation only a singlelocation for the sign needs to be derived, whereas for the trafficcongestion representations (e.g., the traffic patterned line segments) aspan along a length of a road needs to be defined.

The rendering pipeline 1200 is just one conceptual example of themapping application's rendering pipeline of some embodiments thatrenders traffic congestion over or along the roads in the map. In otherembodiments, the rendering pipeline of the mapping application differsfrom the rendering pipeline 1200 of FIG. 12. One alternative renderingpipeline will be described below by reference to FIG. 17B.

FIG. 13 conceptually illustrates how each entry of a linking object ismapped to geometry data of a corresponding road object in someembodiments. It also illustrates how traffic congestion patterns arespecified for different portions of a road. In these embodiments, thestatic road object 1130 is a road tile that specifies the road in a mapsection (e.g., map tile). As shown, this figure includes the map view ofa road vector tile 1310, a data structure view of a linking tile 1320,and a data structure view of the dynamic road condition object, which inthis example is a traffic tile 1395.

The road vector tile 1310 represents a square geographic area of theworld. As shown in the figure, this particular tile contains two roadswith feature identifications (IDs) 10 and 13 that cross over each other.Each road includes several vertices connected in sequence. For the roadwith feature ID 10, there are three traffic segments TSEG 1, TSEG 2, andTSEG 3 within this tile. These traffic segments are defined by thelinking tile 1320, and are used by the traffic tile, as furtherdescribed below. Also, as further described below, the traffic tile 1395can specify one or more congestion patterns for each traffic segment.

As shown by the data structure 1320 of the linking tile, the linkingtile 1320 contains several entries 1325-1335. Each linking tile entryincludes information for mapping a traffic segment to a road thatcontains the traffic segment. Each linking tile entry contains a featureID field, a traffic segment ID field, an offset field, and a lengthfield. The feature ID field identifies a geometric feature (e.g., a roador road segment) in the corresponding road vector tile. The trafficsegment ID field uniquely identifies a portion of a road or road segmentfor which traffic data is provided in the corresponding traffic tile.The offset and length fields describe the corresponding startinggeometry vertex and the length (expressed in vertices in this example)for the road portion represented by the traffic segment ID within theroad represented by the feature ID. These two attributes, offset andlength, specify how the mesh builder should traverse along the road orroad segment identified by the feature ID to identify the varioustraffic segments along this road or road segment. In some embodiments,the mesh builder does this operation after the road representation hasbeen defined by it or another mesh builder. Alternatively, the meshbuilder does this operation independently of the building of the road byit or another mesh builder by simply using the definition of the road orroad segment from the road tile to complete the definition of thetraffic segment, after which it can then specify the traffic congestionrepresentation.

The linking tile layer allows the traffic navigation system to splitstatic traffic content from the dynamic traffic content. Static trafficcontent (e.g., feature ID, traffic segment ID, and offset and length) isstored in the linking tile. A traffic server references traffic segmentsin linking tiles through the traffic segment IDs that are used by boththe traffic and linking tiles. Specifically, as shown in FIG. 13, eachtraffic tile 1395 includes a sequence of traffic flow entries, with eachentry containing a traffic segment ID and traffic data for the trafficsegment. In this example, the traffic data for each traffic segment(TSEG) is expressed in terms of one or more sets of start, end and colorvalues. The start and end values in some embodiments are offset valuesthat are expressed in units relative to overall length of the trafficsegment. In this example, the start and end values are specified asnumbers between 0.0 to 1.0. The color value for each traffic segmentportion (that is specified by color value's corresponding start and endvalues) provides the traffic congestion color for the traffic segmentportion. The color value can have one of three values in someembodiments in order to indicate one of three traffic conditions.Specifically, in some embodiments, the color values can be no color, redcolor and orange color to indicate no traffic congestion, heavy trafficcongestion and moderate traffic congestion. By providing the ability tospecify different traffic conditions for portions for a traffic segment(through the start, end and color values), the traffic tile 1395 allowsthe device to specify traffic congestion along a traffic segment at amore granular level. This ability is useful when a traffic segment islong and hence can have varied traffic congestion across it.

For each entry in the linking tile, the mapping application looks upfeature ID in the corresponding road vector tile for geometryinformation. The application also uses the traffic segment ID toretrieve from the traffic tile the corresponding traffic data that wasreceived from a traffic server for the traffic segment. The applicationthen uses the retrieved traffic data to represent traffic on or adjacentto a road on the map according to (1) the road data in the road objects(tiles), (2) the offset and length fields of the linking objects (tiles)1320, and (3) the start, length and color values in the traffic objects(tiles) 1395.

Specifically, in some embodiments, the traffic tiles express the trafficconditions by storing different color values for different portions oftraffic segments that are defined along a road, as mentioned above. Inthese embodiments, the mapping application retrieves the traffic colorfor a traffic segment portion from the traffic tile, and supplies thiscolor to its mesh builder to represent traffic along a portion of theroad that includes the traffic segment portion (i.e., the portion of theroad associated with the traffic segment ID as specified by the startand length values stored in the traffic tile 1395 for that portion). Asmentioned above, some embodiments uses (1) dashed red lines to representheavy traffic congestion, (2) dashed orange lines to represent moderatetraffic congestion, and (3) the absence of any lines to represent thelack of traffic along a traffic segment. Accordingly, in the embodimentsthat express traffic condition in terms of colors, the traffic tilestores no color value or stores a default color value when no coloredline needs to be drawn for the traffic segment, and this absence ofcolor or this use of default color informs the mesh building pipelineand rendering engine that it does not need to generate any patternedcolor lines to indicate heavy or mild congestion along a route.

In the example illustrated in FIG. 13, the linking tile 1320 has threeentries. The first entry 1325 maps traffic segment 1 to road feature 10with an offset of 0 and a length of 2. The second entry 1330 mapstraffic segment 2 to road feature 10 with an offset of 2 and a length of4. The third entry 1335 maps traffic segment 3 to road feature 10 withan offset of 6 and a length of 2.

As shown in the road vector tile 1310, the traffic segment 1 (TSEG 1)starts from the left most vertex 1350 of the road feature 10 because theoffset of traffic segment 1 is 0, as defined by the linking tile entry1325. The traffic segment 1 continues for two vertices until it reachesvertex 1355 because its length is 2. Similarly, the traffic segment 2(TSEG 2) starts from vertex 1355 of the road feature 10 because theoffset of traffic segment 2 is 2, as defined by the linking tile entry1330. The traffic segment 2 continues for four vertices until it reachesvertex 1360 because its length is 4. The traffic segment 3 (TSEG 3)starts from vertex 1360 of the road feature 10 because the offset oftraffic segment 3 is 6, as defined by the linking tile entry 1335. Thetraffic segment 3 continues for two vertices until it reaches vertex1365 because its length is 2.

With the help of the linking tile 1320, a device can look up feature ID10 in the road vector tile 1310 for corresponding geometry information.The client device also looks up traffic flow data by taking the trafficsegment IDs 1-3 and retrieving traffic data for one or more portions ofthe traffic segment from the traffic tiles. In the example illustratedin FIG. 13, the traffic tile 1395 has (1) a start, end and color datatuple to specify one traffic portion for the first traffic segment, (2)three start, length and color tuples to specify three traffic portionsfor the second traffic segment, and (3) two such data tuples (eachhaving start, end and color values) to specify two traffic portions forthe third traffic segment.

By using the different colors specified for different portions ofdifferent traffic segments and correlating each of the traffic segmentsto a particular road, the client device draws appropriate trafficrepresentation (e.g., appropriate color) on or adjacent to a roadfeature (e.g., road feature 10). Specifically, the device draws theheavy and moderate traffic representations according to (1) the roaddata in the road tiles, (2) the offset and length fields of the linkingtile entries 1325-1335 and (3) the start and length offset fields thatare stored for the traffic segments in the traffic tile 1395.

FIG. 14 presents a process 1400 that conceptually illustrates theoperations of a traffic mesh builder that is directed by a traffic tileprovider to build a mesh that specifies the traffic congestion for aparticular view of the map. As shown in this figure, this operationinitially identifies (at 1410) the zoom level for viewing the tile. Thezoom level determines a particular area of the map to display with aparticular level of detail. In some embodiments, the zoom level is adefined range of distances of the virtual camera from the map (e.g.,along the z axis of a 3D map scene). The zoom level in some embodimentsgoverns how the process 1400 will draw the traffic patterns. Forinstance, as described above, the mapping application draws the trafficpatterns over the roads for certain high zoom levels that result inwider roads, while it draws the traffic patterns adjacent to the roadsfor certain lower zoom levels that result in narrower roads.

Next, at 1420, the process identifies all road segments, trafficsegments, and traffic segment portions that are part of the map viewthat has to be rendered in order to identify the color of the trafficsegment portions that are specified in the dynamic traffic tiles forthat view. To do this, the process identifies one or more static roadtiles that relate to that view and the road segments that are specifiedin those static road tiles. It also identifies the traffic segments forthese road segments through the linking tile or tiles for the identifiedstatic road tile or tiles. For these traffic segments, the process thenuses the dynamic traffic tile(s) associated with the linking tile(s) toidentify the colors that specify the traffic congestion along theportions of the identified traffic segments.

Also at 1420, the process then determines whether there are any routesdisplayed in the map view, and if any such routes exists, determineswhether any traffic congestion pattern (e.g., for showing heavy ormoderate traffic conditions) are sufficiently adjacent to any identifiedroute such that their appearance has to be modified. As mentioned above,different embodiments modify the appearance of the traffic congestionpatterns differently. For instance, as mentioned above, the process 1400changes the appearance of the traffic indicating patterns when they are(1) under the identified path of a displayed route, (2) are near such anidentified path, and/or (3) are near such an identified path and are forthe same direction as the identified path. In some embodiments that drawtraffic patterns over the roads for some zoom levels and along the roadsfor other zoom levels, the process adjusts the appearance of trafficpatterns (1) that are under any identified route when such patterns areto be rendered over the road, and (2) that run along any identifiedroute in the same direction as the route when such patterns are to berendered along the road.

Next at 1430, the process directs one or more mesh building processorsto generate the geometric and color description of the polygons (e.g.,triangles) that define the traffic patterns (e.g., the patterns thatshow heavy and moderate traffic conditions). To do this, the processprovides to the mesh building processors the description of each trafficsegment portion for which traffic congestion patterns have to begenerated. In some embodiments, this description is generated at leastpartially based on (1) the traffic segment offset and length parametersin the linking tiles, (2) the color, start and length data tuples of thetraffic segment portions in the dynamic traffic tiles, and (3) thedefinition of the roads in the road tiles.

Thus, the references to traffic segments in the dynamic traffic tilesand the association of traffic segments to roads in the roads linkingtiles allow the description of the traffic representation for a trafficsegment portion to be derived from the definition of the road tiles. Thedescription is expressed differently in different embodiments. In someembodiments, this description includes copies of the definition of theroad portion corresponding to the traffic segment portion. In otherembodiments, this description includes references to the definition ofthe road portion corresponding to the traffic segment portion.

The generation of the traffic representations (at 1430) also accountsfor whether a traffic representation of a traffic segment portion isbeing drawn over its corresponding road portion or along itscorresponding road portion. As mentioned above, at lower zoom levels(corresponding to a more zoomed out view) the roads might be too narrowto draw the traffic representation over, while at higher zoom levels(correspond to a more zoomed in view) the roads are wide enough to drawthe traffic representation over. Accordingly, at 1430, the processdetermines the zoom level and generates the traffic representationdescription accordingly to go over or along its corresponding roadportion.

After the geometric and color descriptions have been generated, theprocess 1400 provides this information in form of tiles (e.g., buildtraffic tiles) to the modules responsible for directing the rendering ofthe map view. As described above, the built traffic tiles are suppliedin some embodiments to a traffic tile provider, which in turn suppliesthese tiles to the controller to combine with road tiles. In theseembodiments, the controller then supplies the combined tile data to therendering engine for rendering, as described above.

After 1440, the process determines (at 1450) whether it has beeninformed of a change in the zoom level or view angle that wouldnecessitate generation of new geometric and color description for a newsection of the map. If so, it returns to 1410 to repeat operations1410-1440. Otherwise, it determines (at 1460) whether it has beendirected to end (e.g., upon the shutdown of the application, the turningoff of the traffic reporting, etc.). If not, the process returns to 1450to ascertain whether a new request for a new zoom level or new view hasbeen received. Otherwise, the process ends.

C. Simplifying Use of Traffic Data for Changing Deployed Base of Devices

For different reasons, different devices might have different versionsof static road objects. For instance, different devices might updatetheir mapping applications at different time periods, and differentversions of the mapping applications may use different versions ofstatic road objects. Alternatively, in some embodiments, differentdevices might update their map data at different time periods, anddifferent versions of the maps may use different versions of static roadobjects.

The linking object layer allows the traffic server(s) (that generate thedynamic traffic objects or the data for the dynamic traffic objects) tosupport different devices with one set of dynamic traffic objects (e.g.,one set of traffic tiles). This is because the linking objects containtraffic segment IDs that allow the latest version of dynamic trafficobjects to connect to any static road object as they create the desiredassociation between any feature ID (old or new) and the traffic segmentsidentified in the dynamic traffic objects. In other words, themotivation for having this set of shared IDs and the linking objects isto make the traffic server serve client devices based on its ownversion, i.e., the version of its dynamic traffic objects, regardlesswhat versions of road vector objects (e.g., tiles) the client devicesmay have. In other words, the traffic server is insulated from thechanging versions of the road vector objects, because the linking objectlayer can be used to facilitate the translation of a single version ofdynamic traffic objects into detailed geographic locations on a map bydevices that use different versions of static road objects.

FIG. 15 conceptually illustrates how the linking objects make thetraffic server version independent. Specifically, this figure shows thatthe traffic server is able to maintain a single version of dynamictraffic objects (e.g., single version of dynamic traffic tiles) whilesome client devices upgrade to new versions of road vector objects(e.g., road vector tiles) and some client devices continue to use olderversions of road vector objects. In this figure, three time periods 1-3,arranged in chronological order, are illustrated to show how versions ofroad objects on client devices change over time and how the linkingobject layer changes accordingly to enable the traffic server tomaintain a single version of dynamic traffic objects at all times.

At time period 1, each of the devices A, B, and C uses the same versionV1 of road object 1515. The traffic server provides the same version V1of traffic object 1510 to all client devices. Each of device A, B, and Calso stores version V(1, 1) linking object 1512 to map trafficinformation in the traffic object 1510 into geographic locations on roadvector object 1515.

At time period 2, device B and C upgrade their road vector objects 1528to version V2 and the traffic server has also upgraded its trafficobject 1520 to version V2. Device A maintains its road vector objects1515 at version V1. As a result, device A has downloaded linking objectversion V(1, 2) 1522 to make the new V2 traffic object 1520 work withthe old V1 road object 1515, as device A has not needed to download newroad objects. Devices B and C have downloaded linking object versionV(2, 2) 1525 to make the new V2 traffic object 1520 work with the new V2road object 1528 that they have also received or will receive because oftheir upgrade. Because of the linking object layer, the traffic servercan maintain a single version of traffic object 1520 to serve twodifferent versions of road objects (e.g., road vector tiles) on clientdevices during the second time period.

At time period 3, device C upgrades its road vector objects 1538 toversion V3. Device A maintains its road vector objects 1515 at versionV1 and device B maintains its road vector objects 1528 at version V2.The traffic server has also upgraded its traffic objects 1530 to versionV3. As a result, device A has downloaded linking object version V(1, 3)1532 to make the new V3 traffic object 1530 work with the old V1 roadobject. Device B has downloaded linking object version V(2, 3) 1535 tomake the new V3 traffic object 1530 work with the old V2 road object.Device C has downloaded linking object version V(3, 3) 1536 to make thenew V3 traffic object 1530 work with the new V3 road vector object 1538that it has received or will receive because of its upgrade. Because ofthe linking object layer, the traffic server can maintain a singleversion of traffic object 1530 to serve three different versions of roadobjects (e.g., road vector tiles) on client devices during the thirdtime period.

Every time a new version of road objects is generated, the dynamictraffic objects will be generated just for that version in someembodiments. Hence, in these embodiments, new sets of linking objectsare not only supplied to client devices that receive upgraded roadobjects, but also to client devices that do not receive upgraded roadobjects, so that both groups of devices can use the same newer versionof the dynamic traffic objects. However, the different groups of devicesreceive different linking object layers, because the former devicesreceive linking object layers that connect newer traffic objects tonewer static road objects, while the latter devices receive linkingobject layers that connect newer traffic objects to older static roadobjects.

D. Hierarchical Roads, Linking, and Traffic Tile Data

Some embodiments of the invention define the static road objects as ahierarchical set of static road vector tiles that define a map (or asection of a map) for a plurality of zoom levels for viewing the map.For instance, in some embodiments, the device allows the map to beviewed at a large number of zoom levels (e.g., 21 zoom levels). For eachof these zoom levels, the device has a set of static road tiles thatdisplays the roads at that zoom level.

In these embodiments, each road vector tile is defined at a particularzoom level, e.g., from zoom level 1 to zoom level 21, and there is a 1:1relationship between the road vector tile and the linking tile. In otherwords, each road vector tile has a corresponding linking tile.Accordingly, each linking tile also has a zoom level, e.g., from zoomlevel 1 to zoom level 21. Also, in some of these embodiments, thetraffic data is provided at a single zoom level and applied to roadvector tiles for a range of zoom levels. One such approach will now bedescribed by reference to FIGS. 16 and 17.

FIG. 16 illustrates an exemplary hierarchical structure that organizesstatic road tiles at different zoom levels in a quadtree. This figurealso shows that traffic data at a single zoom level, e.g., zoom level 8,can be used for road vector tiles from levels 7 to 15. Morespecifically, the quadtree 1600 is a data structure in which eachnon-leaf node has exactly four children. In some embodiments, each nodeof the quadtree 1600 represents a road tile of a map at a particularzoom level. The four children of each non-leaf node in the treepartition the geographic area covered by the non-leaf node into fourquadrants or regions. Each child node represents a road tile at a zoomlevel that is one level below its parent.

The root node 1605 of the quadtree 1600 is a road tile at zoom level 1.It covers the entire map region. At zoom level 2, the geographical areacovered by the root node 1605 is divided into four regions representedby four road tiles 1610-1618. At zoom level 3, the geographical areacovered by each of the tiles 1610-1618 is divided into four even smallerroad vector tiles. This process goes on until reaching a leaf node,e.g., at zoom level 21.

FIG. 16 illustrates that the dynamic traffic data tiles are provided ata single zoom level, zoom level 8. In contrast to linking tiles thathave to be defined at the same zoom level as their corresponding staticroad tiles, dynamic traffic data at zoom level 8 can be applied in someembodiments to road tiles from zoom levels 7-15 , because of theexistence of traffic segment IDs. The traffic segment IDs are a set ofglobally unique IDs that can be used at all zoom levels. Each trafficsegment ID represents a stretch of paved road in the map. For road tilesat different zoom levels, this stretch of road may be drawn with adifferent number of pixels and with different thickness. But they stillrefer to the same physical stretch of pavement through the same trafficsegment ID in their corresponding linking tiles. Therefore, the dynamictraffic data provided at the single zoom level can be used to scalethrough other zoom levels through the traffic segment ID.

FIG. 16 illustrates that the dynamic traffic data tiles at zoom level 8can be used for static road tiles from zoom levels 7-15 in someembodiments, in other embodiments these traffic data tiles are used forother zoom levels above zoom level 7 and below zoom level 15. Forinstance, the traffic tiles are used at zoom levels below 15 (e.g., 20or 21) that are used for 3D turn-by-turn navigation in some embodiments.Also, while the embodiments described above and below only providetraffic data tiles for one zoom level, other embodiments provide trafficdata tiles at multiple zoom levels.

FIG. 17A further illustrates the concept of providing traffic data at asingle zoom level and applying it to static road tiles and linking tilesfor a range of zoom levels. Specifically, this figure illustrates adynamic traffic condition object at one zoom level being applied tostatic road objects at several different zoom levels. As shown, thedynamic traffic conditions object 1705 is applied to static road objects1750-1780 through the mapping of linking objects 1710-1740.

In some embodiments, the dynamic traffic condition object 1705 isprovided at zoom level 8 for optimal performance. However, it will beclear and apparent to one skilled in the art that the dynamic trafficcondition object can be provided at another zoom level. If the dynamictraffic condition object is provided at a higher zoom level, everytraffic segment will cover a longer section of a road and the accuracyof the traffic information on a map goes down. If the dynamic trafficcondition objection is provided at a lower zoom level, the accuracy ofthe traffic information on a map goes up but the volume of datatransmitted between the client devices and the server increases. Hence,it is important to choose a zoom level for dynamic traffic conditionobjects in order to achieve optimal performance.

A dynamic traffic condition object can be used for static road objectsat the same zoom level. For example, the dynamic traffic conditionobject 1705 is used for static road object 1750 through the mapping ofthe linking object 1710. Both the static road object 1750 and thelinking object 1710 are at zoom level 8, which is the same zoom level asthe dynamic traffic condition object 1705.

A dynamic traffic condition object can also be used for static roadobjects at zoom levels below its own zoom level. For example, thedynamic traffic condition object 1705 is used for static road objects1760 and 1770 through the mappings of the linking objects 1720 and 1730.The static road object 1760 and the linking object 1720 are at zoomlevel 9. The static road object 1770 and the linking object 1730 are atzoom level 10.

A dynamic traffic condition object can also be used for static roadobjects at zoom levels above its own zoom level. For example, in theembodiment illustrated in FIGS. 16 and 17, the dynamic traffic conditionobject 1705 is used for static road object 1780 through the mapping ofthe linking object 1740, where both the objects 1780 and 1740 aredefined at the zoom level 7, which is above the zoom level of thedynamic traffic condition object 1705.

FIG. 17B illustrates a conceptual illustration of an alternativerendering pipeline 1255 of the mapping application for some embodimentsof the invention. This pipeline 1255 is identical to the pipeline 1250of FIG. 12 except that pipeline 1255 includes a dynamic traffic tileprovider 1265 and it uses the traffic tile provider 1230 as theinterface between the controller and the road tile provider 1240, aswell as the interface between this controller and the dynamic traffictile provider 1265.

As described above by reference to FIG. 17A, some embodiments providedynamic traffic tiles only at one particular zoom level. For suchembodiments, the pipeline 1255 uses the dynamic traffic tile provider togenerate dynamic traffic data for roads shown at other zoom levels forwhich traffic congestion can be rendered in some embodiments. In someembodiments, the dynamic traffic tile provider has the sameresponsibilities as the other tile providers but its implementation isdifferent because dynamic tiles are only available at one zoom level.Accordingly, the dynamic tile provider generates dynamic tiles forrendering at zoom levels higher and lower than those described by theprovided dynamic tiles. This requires the dynamic tile provider tosupport a many-to-many relationship between the tiles that it generatesand the dynamic traffic tiles that are provided by the servers 1204.

In the pipeline 1255 of FIG. 17B, the traffic tile provider poses as theroad tile provider for the controller 1250 when traffic congestion needsto be rendered, but attaches extra traffic rendering resources to roadtiles when such resources are available. When the controller asks thetraffic tile provider for a tile, the traffic tile provider 1230 proxiesthe request to the road tile provider 1240. At the same time, it ensuresthat either it already has a static traffic tile (i.e., a linking tile)ready or it has queued a request for one. Similarly, it asks the dynamictile provider to ensure that it has a dynamic tile ready or it hasqueued a request for one. Once the traffic tile provider 1230 notes thatit has all the necessary stored tiles for a particular virtual tile thatit has to generate, it attempts to produce traffic for that virtualtile.

In other words, the process of producing traffic for a virtual tilerequires synchronizing loading between the three types of tiles (dynamictraffic tile 1170, linking tile 1180, and static road tile 1130)provided by the three types of tile provider (dynamic tile provider1265, traffic tile provider 1230, and road tile provider 1240). Thetraffic tile provider is effectively the controller of thiscommunication and thus all tiles flow through it. Once all the tiles areavailable, the traffic tile provider asynchronously generates renderingresources (e.g., the mesh building resources, such as the triangulator,shadow generator, texture decoder, etc.) for traffic using theinformation from the three tiles.

In FIG. 17B, the road tile provider 1230 is shown to have a connectionto the controller 1250 even though in the discussion above it was statedthat the traffic tile provider 1230 serves as the interface between theroad tile provider 1240 and the controller 1250. This connection isshown in FIG. 17B because when traffic congestion is not being displayedon the map, the traffic tile provider 1230 is not being used. Hence, inthis situation, the controller 1250 and the road tile provider 1230 haveto directly interface to generate virtual road tiles for rendering.

III. Compact Route Definition

Some embodiments of the invention provide a novel encoding scheme forexpressing routes in a compressed manner. In some embodiments, a routeserver encodes or compresses routes by removing unnecessary controlpoints from the routes. A control point in some embodiments is a pieceof data (e.g., maneuver instruction) that specifies a road segment towhich to advance from a juncture of the route. A juncture is a locationin a map where two or more road segments meet. The route server providescompressed routes to route clients that decode the routes.

The route server in some embodiments generates a route from a startingpoint to an ending point with a control point at every juncture. Theroute server then determines, for every control point in the route,whether the control point is necessary. The route server removesunnecessary control points from the routes and sends the routes to theroute clients.

The route clients in some embodiments include a mapping application,which generates directions for a user by decoding the compressed routes.In some cases, the map data that the route server used to generate thecompressed routes is not the same map data that the mapping applicationuses to decode the compressed routes. The mapping application employs anovel method of rendering the routes on a map even if the map data usedby the route server and the map data used by the mapping application donot match.

In some cases, the mapping application sends a compressed route toanother server for further analysis (e.g., ETA to the ending location).In some embodiments, the mapping application of some embodiments reducesthe compressed route to send to the other server by removing controlpoints that have been consumed by the mapping application.

In this Section, subsection A describes the route server of someembodiments that generates and compresses routes. Subsection B thendescribes the mapping application of some embodiments that decodes thecompressed routes. Finally, subsection C then describes the mappingapplication of some embodiments that passes the compressed route toanother client in an efficient manner.

A. Route Generation and Encoding

FIG. 18 illustrates conceptual representations of a route generated bythe route server of some embodiments. Specifically, this figureillustrates a route representation 1810 that has a control point atevery juncture in the route and a route representation 1850 that hascontrol points at some of the junctures in the route. As shown, the lefthalf of FIG. 18 illustrates the route representation 1810 overlaid on amap 1800 and the right half of FIG. 18 illustrates the routepresentation 1850 overlaid on the map 1800. The route server of someembodiments does not render the route representations 1810 and 1850 andthe map 1800 to display. The map and the route representations aredepicted in this figure for the purpose of describing routes generatedby the route server of some embodiments.

The route server generates a route and transmits the route to themapping application of some embodiments that requested the route. Insome embodiments, the data for the route includes data for the startingpoint, data for the ending point, data for control points, etc. Thestarting point data and the ending point data in some embodimentsinclude the coordinates (e.g., coordinates for the GPS) for the startingpoint and the ending point. The control point data includes informationof the juncture on which the control point is placed and the direction(e.g., name of the road) which to advance from the juncture. Theinformation of the juncture may include coordinates of the juncture,names of the roads that make up the juncture, the geometric attributesof the juncture, etc. The mapping application of some embodimentsreconstructs the route based on the route data.

The route server of some embodiments places a control point at everyjuncture when the route server initially generates the route between thestarting point and the ending point. As such, the size of route datathat is transmitted to the mapping application is proportional to thenumber of junctures and control points. When there are numerousjunctures, the size of the route data therefore may grow very large inthese embodiments. The route representation 1810 represents an exampleof route data generated by the route server of these embodiments. Asshown, the route representation 1810 has a control point indicator 1805that represents a control point at every juncture in the route that isdepicted as thick black line in the map 1800. The route has the startingpoint 1820 and the ending point 1840.

In other embodiments, the route server removes control points from someof the junctures in the route. The route server removes control pointsthat are not necessary for the mapping application to reconstruct theroute. Determining whether a control point is necessary forreconstructing the route will be described further below. By removingthe data for control points from the route data, the route server ofthese embodiments reduces the size of the route data to send to themapping application of some embodiments. The route representation 1850represents an example of route data generated by the route server ofthese embodiments. As shown, only some of the junctures of the routehave control point indicators 1805. The number of control points in theroute representation 1850 is much smaller (i.e., 4 vs. 10) than thenumber of control points in the route representation 1810.

FIG. 19 conceptually illustrates a process 1900 of some embodiments forencoding route representations as a minimum number of control points.The process 1900 in some embodiments is executed by a route server. Theprocess 1900 starts once the route server has received a starting pointand an ending point from a requesting mapping application.

As shown, process 1900 begins by generating (at 1910) a route withcontrol points at each juncture along the route. A route in someembodiments includes a set of maneuver instructions (or maneuveringinstructions) that directs a person or a device through a set ofjunctures from a starting point to an ending point. More specifically, amaneuvering instruction is associated with each juncture of the routeand the maneuvering instruction identifies a road segment to which toadvance from the juncture.

Next, process 1900 selects (at 1920) the next control point. If nocontrol point is currently selected by process 1900, then the nextcontrol point selected will be the first control point following thestart point of the route. Control points describe what maneuver shouldbe used to traverse a juncture while staying on a route. For example,where a route requires a person or a device to take a right turn througha juncture (where a right turn is necessary to stay on the route), thecontrol point will describe a right turn. In some embodiments, eachcontrol point is associated with each juncture in a route. The process1900 employs one or more routing algorithms to produce control points.

Once process 1900 has selected (at 1920) a control point forconsideration, process 1900 determines (at 1930) whether the selectedcontrol point is necessary. In some embodiments, the route server andthe mapping application share a set of default direction rules based onwhich to determine a direction (or a road segment) to which to advancefrom a juncture. In some embodiments, process 1900 executes the set ofdefault direction rules on the juncture to produce the maneuverinstruction for the associated juncture. Producing a maneuverinstruction for a juncture based on the set of default direction rulesin some embodiments will be described further below.

Whether a control point is necessary is based on whether the maneuverinstruction generated based on the set of default direction rules is thesame as the maneuver instruction of the selected control point. That is,whether a control point is necessary is based on whether the two roadsegments identified by the two maneuvering instructions (one instructiongenerated based on the set of default direction rules and the otherinstruction is of the control point) are identical. When the maneuverinstruction produced based on the set of default direction rules isdifferent than the maneuver instruction of the control point, theprocess 1900 determines that the control point is necessary. That is,when the road segment identified by the maneuver instruction producedbased on the set of default direction rules is different than the roadsegment identified by the maneuver instruction of the control point, theprocess 1900 determines that the maneuver instruction of the controlpoint is necessary.

In some such embodiments, whether a control point is necessary is alsobased on whether there is a road segment that is close to the roadsegment identified by the maneuvering instruction of the control pointand by the maneuvering instruction generated based on the set of defaultdirection rules. The process 1900 determines whether there is such roadsegment based on certain criteria. For instance, when another road thatmakes up the associated juncture is within certain number of degrees(e.g., ten degrees) to the road segment identified by the two maneuverinstructions, the process 1900 determines that (the maneuveringinstruction of) the control point is necessary even if the maneuveringinstruction of the control point is the same as the maneuveringinstruction generated based on the set of default direction rules.

When the process 1900 determines (at 1930) that the selected controlpoint is necessary, the process 1900 proceeds to 1950, which will bedescribed further below. When the process 1900 determines (at 1930) thatthe selected control point is not necessary, the process 1900 removes(at 1940) the control point from the route. In some embodiments, theprocess 1900 removes the control point from the route by removing thedata for the selected control point from the route data that the process1900 generated (at 1910).

Next, the process 1900 determines (at 1950) whether there are controlpoints left in the route of which the process 1900 has not determinedthe necessity of yet. When the process 1900 determines (at 1950) thereare more such control points in the route, the process 1900 loops backto 1920 to select the next control point. Otherwise, the process ends.

Some embodiments that perform the process 1900 generate the route andcontrol points and then traverse the route to examine each juncture todetermine the necessity of the control point associated with thejuncture. Alternatively, the process 1900 of other embodiments maygenerate control points as the process 1900 generates the route. Thatis, the process 1900 in these embodiments alternates generation of acontrol point and determination of the necessity of the control point.

FIGS. 20 and 21 illustrate four example junctures. Specifically, theexamples shown in these two figures illustrate four different situations2001, 2002, 2101, and 2102 in which the route server of some embodimentsdetermines whether to leave the control points for the junctures. Eachsituation is illustrated in terms of road segments that make up thejuncture, an arrowed solid line representing a maneuver instruction of acontrol point, an arrowed dotted line representing a maneuverinstruction produced based on a set of default direction rules, and acontrol point indicator 1805.

FIG. 20 illustrates the first two situations 2001 and 2002 in thecontext of junctures 2005 and 2010. The situation 2001 shows that themaneuver instruction 2015 (depicted as an arrowed, dotted line)generated based on the set of default direction rules and the maneuverinstruction 2020 (depicted as an arrowed solid line) generated by theroute server of some embodiments match.

In some embodiments, the route server (not shown) determines whether thecontrol point for a juncture is necessary by comparing a maneuverinstruction generated based on a set of default direction rules and themaneuver instruction of a generated control point. When the two maneuverinstructions match (i.e., the maneuver instructions identify the sameroad segment as the outbound road segment for the juncture), the routeserver determines that the control point is not needed. When the twomaneuver instructions do not match (i.e., the maneuver instructionsidentify different road segments from the outbound road segments for thejuncture), the route server determines that the control point isnecessary.

Furthermore, the route server of some embodiments determines whether thecontrol point for a juncture is necessary even when the two maneuverinstructions match (i.e., even when the two maneuver instructionsidentify the same road segment to which to advance from the juncture).The route server of these embodiments determines whether there isanother road segment that is close to the road segment identified by thetwo maneuver instructions. The route server determines that such roadsegment exists when another road segment meets certain criteria forbeing close to the identified road segment. For instance, another roadsegment is determined to be close to the identified road segment whenthe two segments make an angle (from the juncture) within a certaindegree (e.g., ten degrees).

In some embodiments, the route server determines the maneuverinstruction for a juncture based on a set of default direction rules fordetermining the road to which to advance from the juncture. Forinstance, the route server compares a set of attributes associated withthe inbound road segment of a juncture with a set of attributesassociated with another road segment of the juncture. When theattributes of the inbound road segment and the other road segment areclose or exactly match, the route server determines that the other roadsegment should be the outbound road segment for the juncture.

The set of attributes in some embodiments includes a functional classattribute, a form of way attribute, and a heading attribute. Thefunctional class attribute indicates the relative importance of the roadsegment. In some embodiments, road segments with higher relativeimportance are displayed in more zoom levels than road segments withlower relative importance. For instance, interstate freeways aredisplayed in almost all zoom levels whereas unnamed dirt roads aredisplayed only on the most granular zoom levels. The form of wayattribute is based on an industry standard system of road segment typecodes. For instance, when form of way equals one, the form of way is aroad. The heading attribute indicates the angle of deviation from duenorth of the outbound road segment from the juncture associated with theselected control point.

In some embodiments, the set of default direction rules defines that acertain amount of deviation between inbound and outbound road segmentattribute values should be tolerated (i.e., should be deemed matching).For example, when the functional class attributes expressed inquantified values are within a certain threshold difference (e.g. plusor minus one), the functional class attributes are considered matching.As another example, when the heading attributes differ by a certainnumber of degrees (e.g., ten degrees or equivalent value in radians),the heading attributes are considered matching in some embodiments.

The situation 2001 is a situation in which the road segment identifiedas the outbound road segment based on the set of default direction rulesis the same as the road segment identified as the outbound road segmentby the control point. The situation 2001 shows that the juncture 2005includes two road segments 2025 and 2030 of Park Ave. and two roadsegments 2035 and 2040 of Wolfe St. In this situation, the segment 2025of Park Ave. is the inbound road segment of the juncture 2005. In thissituation, the route server determines that the attributes of the roadsegment 2025 and the road segment 2030 are matching because, forexample, the attributes of the two road segments exactly match.Therefore, maneuver instruction 2015 indicates go straight.

The maneuver instruction 2020 (depicted as an arrowed solid line) of thecontrol point also indicates go straight as shown. Accordingly, theroute server removes the control point from the route as indicated byabsence of a control point indicator for the juncture 2005.

In the bottom half of FIG. 20, the situation 2002 shows that themaneuver instruction 2065 (depicted as an arrowed dotted line) generatedbased on the set of default direction rules and the maneuver instruction2070 (depicted as an arrowed solid line) generated by the route serverof some embodiments are different. The situation 2002 is a situation inwhich the road segment identified as the outbound road segment based onthe set of default direction rules is not the same as the road segmentidentified as the outbound road segment identified by the control point.The situation 2002 shows that the juncture 2010 includes two roadsegments 2045 and 2050 of National Ave. and two road segments 2055 and2060 of Federal St. In this situation, the segment 2045 of National Ave.is the inbound road segment of the juncture 2010. In this situation, theroute server determines that the attributes of the road segment 2045 andthe road segment 2050 are matching because, for example, the attributesof the two road segments exactly match. Therefore, the maneuverinstruction 2065 indicates go straight.

However, the maneuver instruction 2070 (depicted as an arrowed solidline) of the control point indicates turn right (i.e., go to thedirection of the road segment 2060) as shown. Accordingly, the routeserver leaves the control point in the route as indicated by a controlpoint indicator for the juncture 2010.

FIG. 21 illustrates the next two situations 2101 and 2102 in the contextof junctures 2105 and 2110. The situation 2101 shows that the maneuverinstruction 2115 (depicted as an arrowed dotted line) generated based onthe set of default direction rules and the maneuver instruction 2120(depicted as an arrowed solid line) generated by the route server ofsome embodiments match. However, this situation shows that the routeserver leaves the control point for the juncture 2105 to avoid thepossible confusion by the user of the mapping application.

The situation 2101 is a situation in which a road segment next to theroad segment identified as an outbound road segment, based on the set ofdefault direction rules as well as based on the control point, is tooclose to the outbound road. In such case, the mapping application ofsome embodiments provides a maneuvering instruction (e.g., “bear rightonto Northern Blvd.”) for the user to see (or hear).

The situation 2101 shows that the juncture 2105 includes two roadsegments 2125 and 2130 of Northern Blvd. and one road segment 2135 ofWestgate Ave. In this situation, the segment 2125 of Northern Ave. isthe inbound road segment of the juncture 2105. In this situation, theroute server determines that the attributes of the road segment 2125 andthe road segment 2130 are matching because, for example, the attributesof the two road segments match or are close enough. Therefore, maneuverinstruction 2115 indicates go slightly right.

The maneuver instruction 2120 (depicted as an arrowed solid line) of thecontrol point also indicates go slightly right as shown. Accordingly,the route server of some embodiments would remove the control point fromthe route because the two maneuvering instructions are identical.However, the route server of some embodiments would not remove thecontrol point from the route as shown by the control point indicator1805 for the juncture 2105. This is because, the road segment 2135 ofthe Westgate Ave. is too close to the outbound road segment 2130 (e.g.,less than 10 degrees apart from the juncture). The user who wouldapproach this junction 2105 from the road segment 2125 may be confusedas to which of the two roads ahead to take.

In the bottom half of FIG. 21, the situation 2102 shows that themaneuver instruction 2165 (depicted as an arrowed dotted line) generatedbased on the set of default direction rules and the maneuver instruction2170 (depicted as an arrowed solid line) generated by the route serverof some embodiments are different. The situation 2102 is a situation inwhich the road segment identified as the outbound road segment based onthe set of default direction rules better matches with the inbound roadsegment than the outbound road segment of the control point does eventhough the outbound road segment of the control point bears the samename as the inbound road segment.

The situation 2102 shows that the juncture 2110 includes two roadsegments 2145 and 2150 of First St. and one road segment 2160 of SecondSt. In this situation, the segment 2145 of First St. is the inbound roadsegment of the juncture 2110. In this situation, the route serverdetermines that the attributes of the road segment 2145 and the roadsegment 2160 of Second St. are matching because, for example, theattributes of the two road segments exactly match or are close enough.Therefore, maneuver instruction 2165 indicates go slightly left.

However, the maneuver instruction 2170 (depicted as an arrowed solidline) of the control point indicates turn right (i.e., go to thedirection of the road segment 2150) as shown. Accordingly, the routeserver leaves the control point in the route as indicated by a controlpoint indicator for the juncture 2110.

B. Route Decoding and Rendering by Client

FIG. 22 conceptually illustrates a process 2200 of some embodiments fordecoding route representations that has been encoded as a minimum numberof control points. The process 2200 in some embodiments is executed by amapping application that receives a route from the route server. Theprocess 2200 starts once the mapping application has sent a startingpoint and an ending point to the route server of some embodiments to geta route generated by the route server. As shown, process 2200 begins byreceiving (at 2210) a route with control points at some junctures alongthe route. Next, process 2200 selects (at 2220) the next juncture. If nojuncture is currently selected by process 2200, then the next junctureselected will be the first juncture at or following the start point ofthe route.

In some embodiments, the process 2200 finds the junctures from map data(e.g., road tiles described above) that may not be the same map datathat the route server had used to generate the route. There are severalpossible reasons that the map data the process 2200 is using isdifferent than the map data the route server used. For instance, themapping application that performs the process 2200 may not havedownloaded the same road tiles that the route server used to generatethe route. Also, map service providers that provide the map data to themapping application and the route server may be different. Therefore,the junctures that the process 2200 uses may not include the full set ofthe junctures that the route server had access to in generating theroute data and control points.

Once process 2200 has selected (at 2220) a juncture for consideration,the process 2200 determines (at 2230) whether the selected juncture hasan associated control point. As mentioned above, the control point datamay include information about the associated juncture. The process 2200in some embodiments uses the juncture information in the control pointdata to determine whether the juncture has an associated control point.

When the process 2200 determines (at 2230) that the selected juncturedoes not have an associated control point, the process 2200 proceeds to2240, which will be described further below. When the process 2200determines (at 2230) that the selected juncture has an associatedcontrol point, the process 2200 identifies (at 2245) the outbound roadsegment for the selected juncture. The process 2200 then proceeds to2250 which will be described further below.

When the process 2200 determines (at 2230) that the selected juncturedoes not have an associated control point, the process 2200 determines(at 2240) the outbound road segment for the juncture based on the set ofdefault direction rules that the route server and the mappingapplication share in some embodiments.

In some embodiments, process 2200 executes these shared defaultdirection rules on the juncture to produce a maneuver instruction forthe selected juncture. By using the shared default direction rules, theprocess 2200 and the route server can produce the same maneuverinstruction. Several examples of producing a maneuver instruction for ajuncture in some embodiments are described above by reference to FIGS.20 and 21.

Next, the process 2200 determines (at 2250) whether there are morejunctures in the route which the process 2200 has not considered yet.When the process 2200 determines (at 2250) there are more such juncturesin the route, the process 2200 loops back to 2220 to select the nextjuncture.

When the process 2200 determines there are no more such junctures in theroute, the process 2200 then sends (at 2260) the route with the outboundroad segment identified or determined for each juncture in the route tothe rendering engine so that the rendering engine can render the routerepresentation on a map to display on a device. The rendering engine andits operations to render the route on a map will be described furtherbelow. The process 2200 then ends.

The mapping application of some embodiments that consumes the compressedroute data (i.e., route data that does not have control point for everyjuncture in the route) uses the set of default direction rules toreproduce the route generated by the route server. Specifically, themapping application of these embodiments uses the set of defaultdirection rules to generate maneuvering instructions for the juncturesof the route that do not have control points. In other words, themapping application uses these default direction rules to figures outhow to stay on the route from a juncture with one control point and ajuncture with the next control point in the route when between these twojunctures there are one or more junctures that do not have controlpoints.

In other embodiments, the mapping application consumes the compressedroute data does not use the set of default direction rules. The mappingapplication of these embodiments produces a route using the route databy computing a fastest or shortest path between two consecutive controlpoints of the compressed route data. In other words, the mappingapplication of these embodiments produces a route from the startinglocation to the destination location by computing a “route” between eachpair of two consecutive control points included in the compressed routedata.

FIG. 23 conceptually illustrates a process 2300 that some embodimentsperform to render a route on a map in order to display the routerepresentation on a device that the mapping application runs. Theprocess 2300 is performed by the mapping application of someembodiments, more specifically by a rendering engine of the mappingapplication. In some embodiments, the mapping application that performsthe process 2300 is running on a device that does not have full map dataincluding geometry for every zoom level. Some conventional devicesdedicated to providing routes have full map data having geometry for thestreets for every zoom level. The process 2300 in some embodimentsstarts when the mapping application completes reconstructing the routefrom the compressed route.

The process 2300 begins by receiving (2310) a decoded route. Asdiscussed above, the decoded route is a set of maneuver instructions,some of which are generated from a set of default direction rules by themapping application and some of which are specified by the controlpoints generated by the route server of some embodiments.

The process 2300 then identifies (at 2320) the zoom level at which themapping application displays the map. Next, the process 2300 selects (at2330) the next juncture in the received route. If no juncture iscurrently selected by process 2300, the next juncture selected would bethe first juncture at or following the start point of the route.

The process 2300 then determines (at 2340) whether geometry of theoutbound road segment for the juncture is available at the identifiedzoom level. As mentioned above, when the map is zoomed in (i.e., at arelatively higher zoom level), more road segments are visible on themap. When the map is zoomed out (i.e., at a relative low zoom level),less road segments are visible on the map. Therefore, depending on thezoom level, the geometry for the outbound road segment for the selectedjuncture may not be available because the road tiles at the particularzoom level may not have the geometry for the outbound road segment.

In some embodiments, the process 2300 also examines road tiles at otherzoom levels to see whether the geometry for the outbound road segmentfor the juncture is available. If the geometry for the outbound roadsegment is available at a zoom level different than the identified zoomlevel, the process 2300 takes the geometry, rescales the geometry ifnecessary (i.e., when the geometry is not expressed in vectors), anduses the geometry.

When the process 2300 determines (at 2340) that the geometry isavailable, the process 2300 proceeds to 2345, which will be describedfurther below. When the process 2300 determines that the geometry is notavailable, the process 2300 at 2350 draws other geometry (e.g., astraight line) to the next juncture. If there is not another juncturethat has not been considered by the process 2300, the next juncture isthe ending point of the route.

When the process 2300 determines (at 2340) that the geometry for theoutbound road segment for the selected juncture is available, theprocess 2300 draws (e.g., renders) (at 2345) the available geometry ofthe outbound road segment on the map.

The process then determines (at 2360) whether there are more availablejunctures in the route which the process 2300 has not considered yet.When the process 2300 determines (at 2360) there are more such juncturesin the route, the process 2300 loops back to 2330 to select the nextjuncture. Otherwise, the process 2300 then ends.

FIG. 24 conceptually illustrates an example of rendering a route at twodifferent zoom levels. Specifically, this figure illustrates that someroad segments of the route are rendered as straight lines in the map andsome road segments of the route are realistically rendered by using thegeometries for those road segments.

The left half of this figure illustrates the route at a relatively lowzoom level (e.g., zoom level 3). In this example, the route is between astarting point 2405 at a location in Southern California and an endingpoint 2425 at a location in Northern California. At this zoom level, themap data (i.e. road tiles) that the mapping application of someembodiments has, does not have geometries for the road segments near thestarting point and the ending point and thus the rendering of someembodiments draws the portions of the route that fall in these roadsegments as straight lines 2410 and 2420. The mapping application inthis example has the geometry for the portions of the route that fall inthe road segments of highways and freeways. Thus, the rendering enginedraws the portion of the route that fall in these road segments usingthe available geometries. As a result, the portion 2415 of the route isrealistically rendered on the map.

The right half of this figure illustrates the portion of the route fromthe starting point 2405 to the ending point 2425 near the starting point2405. Because the map is zoomed in to a relatively high zoom level(e.g., zoom level 10) and the mapping application has the road tilescovering this region of the map at this particular zoom level, therendering engine draws the portions of the route covered by these roadsegments using the geometries for the road segments as shown.

C. Passing Compressed Route to Another Client

FIG. 25 conceptually illustrates an example of sending compressed routedata (1) from a route server that generates the compressed route to afirst client that consumes the compressed route data and then (2) fromthe first client to a second client that consumes the compressed routedata. This figures illustrates a route server 2520, a device 2540, andan ETA server 2560.

The route server 2520 generates a compressed route based on the routerequest 2510 received from the device 2540. The route request 2510 insome embodiments includes starting point data and ending point dataamong other data. In response, the route server 2520 generatescompressed route data 2530. The compressed route data 2530 in thisexample includes two control points depicted as encircled, arrowed linesand the starting and ending points depicted as an encircled “S” and anencircled “E.” In some embodiments, the route server 2520 removes ordoes not place control points from junctures in the route. In someembodiments, the route server 2520 generates the compressed route usingprocess 1900 as described above in conjunction with FIG. 19.

The device 2540 is a device on which the mapping application of someembodiment runs. This mapping application generates a set of maneuverinstructions based on the received compressed route data 2530. Themapping application provides the maneuver instructions to the user whouses the mapping application. In some embodiments, the device 2540generates the set of maneuver instructions using process 2200 asdescribed above in conjunction with FIG. 22.

In some embodiments, the mapping application running on the device 2540provides additional information to the user (e.g., ETA from the currentlocation of the device to the ending point of the route). The mappingapplication in these embodiments uses another server (e.g., the ETAserver 2560) to obtain the data for the additional information (e.g.,ETA from the current location of the device to the ending point of theroute through which the user is currently navigating).

In some embodiments, the mapping application does not send the wholecompressed route data 2530 to the other server (e.g., the ETA server2560) when sending the route data as part of a request for theadditional information (not shown). For instance, the mappingapplication identifies the current location of the device and thenremoves any control point that precedes the current location of thedevice in the route from compressed route data 2530. That is, themapping application of these embodiments identifies only the endingpoint and the control points that the mapping application has notconsumed or decoded to generate maneuver instructions and gets rid ofthe rest from the compressed route data 2530. The mapping application ofsome embodiments thereby reduces (or further compresses) the compressedroute data 2530 and sends the reduced and compressed route data 2550 tothe other server (e.g., the ETA server 2560). As shown, the reduced andcompressed route data 2550 has only one control point. The other server(e.g., the ETA server 2560) then sends back the requested information(e.g., ETA) to the device 2540.

IV. Electronic System

Many of the above-described features and applications are implemented assoftware processes that are specified as a set of instructions recordedon a computer readable storage medium (also referred to as computerreadable medium). When these instructions are executed by one or morecomputational or processing unit(s) (e.g., one or more processors, coresof processors, or other processing units), they cause the processingunit(s) to perform the actions indicated in the instructions. Examplesof computer readable media include, but are not limited to, CD-ROMs,flash drives, random access memory (RAM) chips, hard drives, erasableprogrammable read-only memories (EPROMs), electrically erasableprogrammable read-only memories (EEPROMs), etc. The computer readablemedia does not include carrier waves and electronic signals passingwirelessly or over wired connections.

In this specification, the term “software” is meant to include firmwareresiding in read-only memory or applications stored in magnetic storagewhich can be read into memory for processing by a processor. Also, insome embodiments, multiple software inventions can be implemented assub-parts of a larger program while remaining distinct softwareinventions. In some embodiments, multiple software inventions can alsobe implemented as separate programs. Finally, any combination ofseparate programs that together implement a software invention describedhere is within the scope of the invention. In some embodiments, thesoftware programs, when installed to operate on one or more electronicsystems, define one or more specific machine implementations thatexecute and perform the operations of the software programs.

A. Mobile Device

The mapping and navigation applications of some embodiments operate onmobile devices, such as smart phones (e.g., iPhones®) and tablets (e.g.,iPads®). FIG. 26 is an example of an architecture 2600 of such a mobilecomputing device. Examples of mobile computing devices includesmartphones, tablets, laptops, etc. As shown, the mobile computingdevice 2600 includes one or more processing units 2605, a memoryinterface 2610 and a peripherals interface 2615.

The peripherals interface 2615 is coupled to various sensors andsubsystems, including a camera subsystem 2620, a wireless communicationsubsystem(s) 2625, an audio subsystem 2630, an I/O subsystem 2635, etc.The peripherals interface 2615 enables communication between theprocessing units 2605 and various peripherals. For example, anorientation sensor 2645 (e.g., a gyroscope) and an acceleration sensor2650 (e.g., an accelerometer) is coupled to the peripherals interface2615 to facilitate orientation and acceleration functions.

The camera subsystem 2620 is coupled to one or more optical sensors 2640(e.g., a charged coupled device (CCD) optical sensor, a complementarymetal-oxide-semiconductor (CMOS) optical sensor, etc.). The camerasubsystem 2620 coupled with the optical sensors 2640 facilitates camerafunctions, such as image and/or video data capturing. The wirelesscommunication subsystem 2625 serves to facilitate communicationfunctions. In some embodiments, the wireless communication subsystem2625 includes radio frequency receivers and transmitters, and opticalreceivers and transmitters (not shown in FIG. 26). These receivers andtransmitters of some embodiments are implemented to operate over one ormore communication networks such as a GSM network, a Wi-Fi network, aBluetooth network, etc. The audio subsystem 2630 is coupled to a speakerto output audio (e.g., to output voice navigation instructions).Additionally, the audio subsystem 2630 is coupled to a microphone tofacilitate voice-enabled functions, such as voice recognition (e.g., forsearching), digital recording, etc.

The I/O subsystem 2635 involves the transfer between input/outputperipheral devices, such as a display, a touch screen, etc., and thedata bus of the processing units 2605 through the peripherals interface2615. The I/O subsystem 2635 includes a touch-screen controller 2655 andother input controllers 2660 to facilitate the transfer betweeninput/output peripheral devices and the data bus of the processing units2605. As shown, the touch-screen controller 2655 is coupled to a touchscreen 2665. The touch-screen controller 2655 detects contact andmovement on the touch screen 2665 using any of multiple touchsensitivity technologies. The other input controllers 2660 are coupledto other input/control devices, such as one or more buttons. Someembodiments include a near-touch sensitive screen and a correspondingcontroller that can detect near-touch interactions instead of or inaddition to touch interactions.

The memory interface 2610 is coupled to memory 2670. In someembodiments, the memory 2670 includes volatile memory (e.g., high-speedrandom access memory), non-volatile memory (e.g., flash memory), acombination of volatile and non-volatile memory, and/or any other typeof memory. As illustrated in FIG. 26, the memory 2670 stores anoperating system (OS) 2672. The OS 2672 includes instructions forhandling basic system services and for performing hardware dependenttasks.

The memory 2670 also includes communication instructions 2674 tofacilitate communicating with one or more additional devices; graphicaluser interface instructions 2676 to facilitate graphic user interfaceprocessing; image processing instructions 2678 to facilitateimage-related processing and functions; input processing instructions2680 to facilitate input-related (e.g., touch input) processes andfunctions; audio processing instructions 2682 to facilitateaudio-related processes and functions; and camera instructions 2684 tofacilitate camera-related processes and functions. The instructionsdescribed above are merely exemplary and the memory 2670 includesadditional and/or other instructions in some embodiments. For instance,the memory for a smartphone may include phone instructions to facilitatephone-related processes and functions. Additionally, the memory mayinclude instructions for a mapping and navigation application as well asother applications. The above-identified instructions need not beimplemented as separate software programs or modules. Various functionsof the mobile computing device can be implemented in hardware and/or insoftware, including in one or more signal processing and/or applicationspecific integrated circuits.

While the components illustrated in FIG. 26 are shown as separatecomponents, one of ordinary skill in the art will recognize that two ormore components may be integrated into one or more integrated circuits.In addition, two or more components may be coupled together by one ormore communication buses or signal lines. Also, while many of thefunctions have been described as being performed by one component, oneof ordinary skill in the art will realize that the functions describedwith respect to FIG. 26 may be split into two or more integratedcircuits.

B. Computer System

FIG. 27 conceptually illustrates another example of an electronic system2700 with which some embodiments of the invention are implemented. Theelectronic system 2700 may be a computer (e.g., a desktop computer,personal computer, tablet computer, etc.), phone, PDA, or any other sortof electronic or computing device. Such an electronic system includesvarious types of computer readable media and interfaces for variousother types of computer readable media. Electronic system 2700 includesa bus 2705, processing unit(s) 2710, a graphics processing unit (GPU)2715, a system memory 2720, a network 2725, a read-only memory 2730, apermanent storage device 2735, input devices 2740, and output devices2745.

The bus 2705 collectively represents all system, peripheral, and chipsetbuses that communicatively connect the numerous internal devices of theelectronic system 2700. For instance, the bus 2705 communicativelyconnects the processing unit(s) 2710 with the read-only memory 2730, theGPU 2715, the system memory 2720, and the permanent storage device 2735.

From these various memory units, the processing unit(s) 2710 retrievesinstructions to execute and data to process in order to execute theprocesses of the invention. The processing unit(s) may be a singleprocessor or a multi-core processor in different embodiments. Someinstructions are passed to and executed by the GPU 2715. The GPU 2715can offload various computations or complement the image processingprovided by the processing unit(s) 2710. In some embodiments, suchfunctionality can be provided using a kernel shading language.

The read-only-memory (ROM) 2730 stores static data and instructions thatare needed by the processing unit(s) 2710 and other modules of theelectronic system. The permanent storage device 2735, on the other hand,is a read-and-write memory device. This device is a non-volatile memoryunit that stores instructions and data even when the electronic system2700 is off. Some embodiments of the invention use a mass-storage device(such as a magnetic or optical disk and its corresponding disk drive,integrated flash memory) as the permanent storage device 2735.

Other embodiments use a removable storage device (such as a floppy disk,flash memory device, etc., and its corresponding drive) as the permanentstorage device. Like the permanent storage device 2735, the systemmemory 2720 is a read-and-write memory device. However, unlike storagedevice 2735, the system memory 2720 is a volatile read-and-write memory,such a random access memory. The system memory 2720 stores some of theinstructions and data that the processor needs at runtime. In someembodiments, the invention's processes are stored in the system memory2720, the permanent storage device 2735, and/or the read-only memory2730. From these various memory units, the processing unit(s) 2710retrieves instructions to execute and data to process in order toexecute the processes of some embodiments.

The bus 2705 also connects to the input and output devices 2740 and2745. The input devices 2740 enable the user to communicate informationand select commands to the electronic system. The input devices 2740include alphanumeric keyboards and pointing devices (also called “cursorcontrol devices”), cameras (e.g., webcams), microphones or similardevices for receiving voice commands, etc. The output devices 2745display images generated by the electronic system or otherwise outputdata. The output devices 2745 include printers and display devices, suchas cathode ray tubes (CRT) or liquid crystal displays (LCD), as well asspeakers or similar audio output devices. Some embodiments includedevices such as a touchscreen that function as both input and outputdevices.

Finally, as shown in FIG. 27, bus 2705 also couples electronic system2700 to a network 2725 through a network adapter (not shown). In thismanner, the computer can be a part of a network of computers (such as alocal area network (“LAN”), a wide area network (“WAN”), an intranet, ora network of networks, such as the Internet. Any or all components ofelectronic system 2700 may be used in conjunction with the invention.

Some embodiments include electronic components, such as microprocessors,storage and memory that store computer program instructions in amachine-readable or computer-readable medium (alternatively referred toas computer-readable storage media, machine-readable media, ormachine-readable storage media). Some examples of such computer-readablemedia include RAM, ROM, read-only compact discs (CD-ROM), recordablecompact discs (CD-R), rewritable compact discs (CD-RW), read-onlydigital versatile discs (e.g., DVD-ROM, dual-layer DVD-ROM), a varietyof recordable/rewritable DVDs (e.g., DVD-RAM, DVD-RW, DVD+RW, etc.),flash memory (e.g., SD cards, mini-SD cards, micro-SD cards, etc.),magnetic and/or solid state hard drives, read-only and recordableBlu-Ray® discs, ultra density optical discs, any other optical ormagnetic media, and floppy disks. The computer-readable media may storea computer program that is executable by at least one processing unitand includes sets of instructions for performing various operations.Examples of computer programs or computer code include machine code,such as is produced by a compiler, and files including higher-level codethat are executed by a computer, an electronic component, or amicroprocessor using an interpreter.

While the above discussion primarily refers to microprocessor ormulti-core processors that execute software, some embodiments areperformed by one or more integrated circuits, such as applicationspecific integrated circuits (ASICs) or field programmable gate arrays(FPGAs). In some embodiments, such integrated circuits executeinstructions that are stored on the circuit itself In addition, someembodiments execute software stored in programmable logic devices(PLDs), ROM, or RAM devices.

As used in this specification and any claims of this application, theterms “computer”, “server”, “processor”, and “memory” all refer toelectronic or other technological devices. These terms exclude people orgroups of people. For the purposes of the specification, the termsdisplay or displaying means displaying on an electronic device. As usedin this specification and any claims of this application, the terms“computer readable medium,” “computer readable media,” and “machinereadable medium” are entirely restricted to tangible, physical objectsthat store information in a form that is readable by a computer. Theseterms exclude any wireless signals, wired download signals, and anyother ephemeral signals.

V. Map Service Environment

Various embodiments may operate within a map service operatingenvironment. FIG. 28 illustrates a map service operating environment,according to some embodiments. A map service 2830 (also referred to asmapping service) may provide map services for one or more client devices2802 a-2802 c in communication with the map service 2830 through variouscommunication methods and protocols. A map service 2830 in someembodiments provides map information and other map-related data, such astwo-dimensional map image data (e.g., aerial view of roads utilizingsatellite imagery), three-dimensional map image data (e.g., traversablemap with three-dimensional features, such as buildings), route anddirection calculations (e.g., ferry route calculations or directionsbetween two points for a pedestrian), real-time navigation data (e.g.,turn-by-turn visual navigation data in two or three dimensions),location data (e.g., where the client device currently is located), andother geographic data (e.g., wireless network coverage, weather, trafficinformation, or nearby points-of-interest). In various embodiments, themap service data may include localized labels for different countries orregions. Localized labels may be utilized to present map labels (e.g.,street names, city names, points of interest) in different languages onclient devices. Client devices 2802 a-2802 c may utilize these mapservices by obtaining map service data. Client devices 2802 a-2802 c mayimplement various techniques to process map service data. Client devices2802 a-2802 c may then provide map services to various entities,including, but not limited to, users, internal software or hardwaremodules, and/or other systems or devices external to the client devices2802 a-2802 c.

In some embodiments, a map service is implemented by one or more nodesin a distributed computing system. Each node may be assigned one or moreservices or components of a map service. Some nodes may be assigned thesame map service or component of a map service. A load balancing node insome embodiments distributes access or requests to other nodes within amap service. In some embodiments a map service is implemented as asingle system, such as a single server. Different modules or hardwaredevices within a server may implement one or more of the variousservices provided by a map service.

A map service in some embodiments provides map services by generatingmap service data in various formats. In some embodiments, one format ofmap service data is map image data. Map image data provides image datato a client device so that the client device may process the image data(e.g., rendering and/or displaying the image data as a two-dimensionalor three-dimensional map). Map image data, whether in two or threedimensions, may specify one or more map tiles. A map tile may be aportion of a larger map image. Assembling together the map tiles of amap produces the original map. Tiles may be generated from map imagedata, routing or navigation data, or any other map service data. In someembodiments map tiles are raster-based map tiles, with tile sizesranging from any size both larger and smaller than a commonly-used 256pixel by 256 pixel tile. Raster-based map tiles may be encoded in anynumber of standard digital image representations including, but notlimited to, Bitmap (.bmp), Graphics Interchange Format (.gif), JointPhotographic Experts Group (.jpg, .jpeg, etc.), Portable NetworksGraphic (.png), or Tagged Image File Format (.tiff). In someembodiments, map tiles are vector-based map tiles, encoded using vectorgraphics, including, but not limited to, Scalable Vector Graphics (.svg)or a Drawing File (.drw). Some embodiments also include tiles with acombination of vector and raster data. Metadata or other informationpertaining to the map tile may also be included within or along with amap tile, providing further map service data to a client device. Invarious embodiments, a map tile is encoded for transport utilizingvarious standards and/or protocols, some of which are described inexamples below.

In various embodiments, map tiles may be constructed from image data ofdifferent resolutions depending on zoom level. For instance, for lowzoom level (e.g., world or globe view), the resolution of map or imagedata need not be as high relative to the resolution at a high zoom level(e.g., city or street level). For example, when in a globe view, theremay be no need to render street level artifacts as such objects would beso small as to be negligible in many cases.

A map service in some embodiments performs various techniques to analyzea map tile before encoding the tile for transport. This analysis mayoptimize map service performance for both client devices and a mapservice. In some embodiments map tiles are analyzed for complexity,according to vector-based graphic techniques, and constructed utilizingcomplex and non-complex layers. Map tiles may also be analyzed forcommon image data or patterns that may be rendered as image textures andconstructed by relying on image masks. In some embodiments, raster-basedimage data in a map tile contains certain mask values, which areassociated with one or more textures. Some embodiments also analyze maptiles for specified features that may be associated with certain mapstyles that contain style identifiers.

Other map services generate map service data relying upon various dataformats separate from a map tile in some embodiments. For instance, mapservices that provide location data may utilize data formats conformingto location service protocols, such as, but not limited to, RadioResource Location services Protocol (RRLP), TIA 801 for Code DivisionMultiple Access (CDMA), Radio Resource Control (RRC) position protocol,or LTE Positioning Protocol (LPP). Embodiments may also receive orrequest data from client devices identifying device capabilities orattributes (e.g., hardware specifications or operating system version)or communication capabilities (e.g., device communication bandwidth asdetermined by wireless signal strength or wired or wireless networktype).

A map service may obtain map service data from internal or externalsources. For example, satellite imagery used in map image data may beobtained from external services, or internal systems, storage devices,or nodes. Other examples may include, but are not limited to, GPSassistance servers, wireless network coverage databases, business orpersonal directories, weather data, government information (e.g.,construction updates or road name changes), or traffic reports. Someembodiments of a map service may update map service data (e.g., wirelessnetwork coverage) for analyzing future requests from client devices.

Various embodiments of a map service respond to client device requestsfor map services. These requests may be a request for a specific map orportion of a map. Some embodiments format requests for a map as requestsfor certain map tiles. In some embodiments, requests also supply the mapservice with starting locations (or current locations) and destinationlocations for a route calculation. A client device may also request mapservice rendering information, such as map textures or style sheets. Inat least some embodiments, requests are also one of a series of requestsimplementing turn-by-turn navigation. Requests for other geographic datamay include, but are not limited to, current location, wireless networkcoverage, weather, traffic information, or nearby points-of-interest.

A map service, in some embodiments, analyzes client device requests tooptimize a device or map service operation. For instance, a map servicemay recognize that the location of a client device is in an area of poorcommunications (e.g., weak wireless signal) and send more map servicedata to supply a client device in the event of loss in communication orsend instructions to utilize different client hardware (e.g.,orientation sensors) or software (e.g., utilize wireless locationservices or Wi-Fi positioning instead of GPS-based services). In anotherexample, a map service may analyze a client device request forvector-based map image data and determine that raster-based map databetter optimizes the map image data according to the image's complexity.Embodiments of other map services may perform similar analysis on clientdevice requests and as such the above examples are not intended to belimiting.

Various embodiments of client devices (e.g., client devices 2802 a-2802c) are implemented on different portable-multifunction device types.Client devices 2802 a-2802 c utilize map service 2830 through variouscommunication methods and protocols. In some embodiments, client devices2802 a-2802 c obtain map service data from map service 2830. Clientdevices 2802 a-2802 c request or receive map service data. Clientdevices 2802 a-2802 c then process map service data (e.g., render and/ordisplay the data) and may send the data to another software or hardwaremodule on the device or to an external device or system.

A client device, according to some embodiments, implements techniques torender and/or display maps. These maps may be requested or received invarious formats, such as map tiles described above. A client device mayrender a map in two-dimensional or three-dimensional views. Someembodiments of a client device display a rendered map and allow a user,system, or device providing input to manipulate a virtual camera in themap, changing the map display according to the virtual camera'sposition, orientation, and field-of-view. Various forms and inputdevices are implemented to manipulate a virtual camera. In someembodiments, touch input, through certain single or combination gestures(e.g., touch-and-hold or a swipe) manipulate the virtual camera. Otherembodiments allow manipulation of the device's physical orientation tomanipulate a virtual camera. For instance, a client device may be tiltedup from its current position to manipulate the virtual camera to rotateup. In another example, a client device may be tilted forward from itscurrent position to move the virtual camera forward. Other input devicesto the client device may be implemented including, but not limited to,auditory input (e.g., spoken words), a physical keyboard, mouse, and/ora joystick.

Some embodiments provide various visual feedback to virtual cameramanipulations, such as displaying an animation of possible virtualcamera manipulations when transitioning from two-dimensional map viewsto three-dimensional map views. Some embodiments also allow input toselect a map feature or object (e.g., a building) and highlight theobject, producing a blur effect that maintains the virtual camera'sperception of three-dimensional space.

In some embodiments, a client device implements a navigation system(e.g., turn-by-turn navigation). A navigation system provides directionsor route information, which may be displayed to a user. Some embodimentsof a client device request directions or a route calculation from a mapservice. A client device may receive map image data and route data froma map service. In some embodiments, a client device implements aturn-by-turn navigation system, which provides real-time route anddirection information based upon location information and routeinformation received from a map service and/or other location system,such as a Global Positioning Satellite (GPS) system. A client device maydisplay map image data that reflects the current location of the clientdevice and update the map image data in real-time. A navigation systemmay provide auditory or visual directions to follow a certain route.

A virtual camera is implemented to manipulate navigation map dataaccording to some embodiments. Some embodiments of client devices allowthe device to adjust the virtual camera display orientation to biastoward the route destination. Some embodiments also allow the virtualcamera to navigation turns simulating the inertial motion of the virtualcamera.

Client devices implement various techniques to utilize map service datafrom a map service. Some embodiments implement some techniques tooptimize rendering of two-dimensional and three-dimensional map imagedata. In some embodiments, a client device locally stores renderinginformation. For instance, a client stores a style sheet which providesrendering directions for image data containing style identifiers. Inanother example, common image textures may be stored to decrease theamount of map image data transferred from a map service. Client devicesin different embodiments implement various modeling techniques to rendertwo-dimensional and three-dimensional map image data, examples of whichinclude, but are not limited to: generating three-dimensional buildingsout of two-dimensional building footprint data; modeling two-dimensionaland three-dimensional map objects to determine the client devicecommunication environment; generating models to determine whether maplabels are seen from a certain virtual camera position; and generatingmodels to smooth transitions between map image data. In someembodiments, the client devices also order or prioritize map servicedata in certain techniques. For instance, a client device detects themotion or velocity of a virtual camera, which if exceeding certainthreshold values, lower-detail image data is loaded and rendered forcertain areas. Other examples include: rendering vector-based curves asa series of points, preloading map image data for areas of poorcommunication with a map service, adapting textures based on displayzoom level, or rendering map image data according to complexity.

In some embodiments, client devices communicate utilizing various dataformats separate from a map tile. For instance, some client devicesimplement Assisted Global Positioning Satellites (A-GPS) and communicatewith location services that utilize data formats conforming to locationservice protocols, such as, but not limited to, Radio Resource Locationservices Protocol (RRLP), TIA 801 for Code Division Multiple Access(CDMA), Radio Resource Control (RRC) position protocol, or LTEPositioning Protocol (LPP). Client devices may also receive GPS signalsdirectly. Embodiments may also send data, with or without solicitationfrom a map service, identifying the client device's capabilities orattributes (e.g., hardware specifications or operating system version)or communication capabilities (e.g., device communication bandwidth asdetermined by wireless signal strength or wired or wireless networktype).

FIG. 28 illustrates one possible embodiment of an operating environment2800 for a map service 2830 and client devices 2802 a-2802 c. In someembodiments, devices 2802 a, 2802 b, and 2802 c communicate over one ormore wired or wireless networks 2810. For example, wireless network2810, such as a cellular network, can communicate with a wide areanetwork (WAN) 2820, such as the Internet, by use of gateway 2814. Agateway 2814 in some embodiments provides a packet oriented mobile dataservice, such as General Packet Radio Service (GPRS), or other mobiledata service allowing wireless networks to transmit data to othernetworks, such as wide area network 2820. Likewise, access device 2812(e.g., IEEE 802.11g wireless access device) provides communicationaccess to WAN 2820. Devices 2802 a and 2802 b can be any portableelectronic or computing device capable of communicating with a mapservice. Device 2802 c can be any non-portable electronic or computingdevice capable of communicating with a map service.

In some embodiments, both voice and data communications are establishedover wireless network 2810 and access device 2812. For instance, device2802 a can place and receive phone calls (e.g., using voice overInternet Protocol (VoIP) protocols), send and receive e-mail messages(e.g., using Simple Mail Transfer Protocol (SMTP) or Post OfficeProtocol 3 (POP3)), and retrieve electronic documents and/or streams,such as web pages, photographs, and videos, over wireless network 2810,gateway 2814, and WAN 2820 (e.g., using Transmission ControlProtocol/Internet Protocol (TCP/IP) or User Datagram Protocol (UDP)).Likewise, in some implementations, devices 2802 b and 2802 c can placeand receive phone calls, send and receive e-mail messages, and retrieveelectronic documents over access device 2812 and WAN 2820. In variousembodiments, any of the illustrated client devices may communicate withmap service 2830 and/or other service(s) 2850 using a persistentconnection established in accordance with one or more securityprotocols, such as the Secure Sockets Layer (SSL) protocol or theTransport Layer Security (TLS) protocol.

Devices 2802 a and 2802 b can also establish communications by othermeans. For example, wireless device 2802 a can communicate with otherwireless devices (e.g., other devices 2802 b, cell phones, etc.) overthe wireless network 2810. Likewise devices 2802 a and 2802 b canestablish peer-to-peer communications 2840 (e.g., a personal areanetwork) by use of one or more communication subsystems, such asBluetooth® communication from Bluetooth Special Interest Group, Inc. ofKirkland, Wash. Device 2802 c can also establish peer to peercommunications with devices 2802 a or 2802 b (not shown). Othercommunication protocols and topologies can also be implemented. Devices2802 a and 2802 b may also receive Global Positioning Satellite (GPS)signals from GPS satellites 2860.

Devices 2802 a, 2802 b, and 2802 c can communicate with map service 2830over one or more wired and/or wireless networks, 2810 or 2812. Forinstance, map service 2830 can provide map service data to renderingdevices 2802 a, 2802 b, and 2802 c. Map service 2830 may alsocommunicate with other services 2850 to obtain data to implement mapservices. Map service 2830 and other services 2850 may also receive GPSsignals from GPS satellites 2860.

In various embodiments, map service 2830 and/or other service(s) 2850are configured to process search requests from any of the clientdevices. Search requests may include but are not limited to queries forbusinesses, addresses, residential locations, points of interest, orsome combination thereof. Map service 2830 and/or other service(s) 2850may be configured to return results related to a variety of parametersincluding but not limited to a location entered into an address bar orother text entry field (including abbreviations and/or other shorthandnotation), a current map view (e.g., user may be viewing one location onthe multifunction device while residing in another location), currentlocation of the user (e.g., in cases where the current map view did notinclude search results), and the current route (if any). In variousembodiments, these parameters may affect the composition of the searchresults (and/or the ordering of the search results) based on differentpriority weightings. In various embodiments, the search results that arereturned may be a subset of results selected based on specific criteriaincluding but not limited to a quantity of times the search result(e.g., a particular point of interest) has been requested, a measure ofquality associated with the search result (e.g., highest user oreditorial review rating), and/or the volume of reviews for the searchresults (e.g., the number of times the search result has been reviewedor rated).

In various embodiments, map service 2830 and/or other service(s) 2850are configured to provide auto-complete search results that aredisplayed on the client device, such as within the mapping application.For instance, auto-complete search results may populate a portion of thescreen as the user enters one or more search keywords on themultifunction device. In some cases, this feature may save the user timeas the desired search result may be displayed before the user enters thefull search query. In various embodiments, the auto complete searchresults may be search results found by the client on the client device(e.g., bookmarks or contacts), search results found elsewhere (e.g.,from the Internet) by map service 2830 and/or other service(s) 2850,and/or some combination thereof. As is the case with commands, any ofthe search queries may be entered by the user via voice or throughtyping. The multifunction device may be configured to display searchresults graphically within any of the map display described herein. Forinstance, a pin or other graphical indicator may specify locations ofsearch results as points of interest. In various embodiments, responsiveto a user selection of one of these points of interest (e.g., a touchselection, such as a tap), the multifunction device is configured todisplay additional information about the selected point of interestincluding but not limited to ratings, reviews or review snippets, hoursof operation, store status (e.g., open for business, permanently closed,etc.), and/or images of a storefront for the point of interest. Invarious embodiments, any of this information may be displayed on agraphical information card that is displayed in response to the user'sselection of the point of interest.

In various embodiments, map service 2830 and/or other service(s) 2850provide one or more feedback mechanisms to receive feedback from clientdevices 2802 a-2802 c. For instance, client devices may provide feedbackon search results to map service 2830 and/or other service(s) 2850(e.g., feedback specifying ratings, reviews, temporary or permanentbusiness closures, errors etc.); this feedback may be used to updateinformation about points of interest in order to provide more accurateor more up-to-date search results in the future. In some embodiments,map service 2830 and/or other service(s) 2850 may provide testinginformation to the client device (e.g., an A/B test) to determine whichsearch results are best. For instance, at random intervals, the clientdevice may receive and present two search results to a user and allowthe user to indicate the best result. The client device may report thetest results to map service 2830 and/or other service(s) 2850 to improvefuture search results based on the chosen testing technique, such as anA/B test technique in which a baseline control sample is compared to avariety of single-variable test samples in order to improve results.

While the invention has been described with reference to numerousspecific details, one of ordinary skill in the art will recognize thatthe invention can be embodied in other specific forms without departingfrom the spirit of the invention. For instance, many of the figuresillustrate various touch gestures (e.g., taps, double taps, swipegestures, press and hold gestures, etc.). However, many of theillustrated operations could be performed via different touch gestures(e.g., a swipe instead of a tap, etc.) or by non-touch input (e.g.,using a cursor controller, a keyboard, a touchpad/trackpad, a near-touchsensitive screen, etc.). In addition, a number of the figuresconceptually illustrate processes. The specific operations of theseprocesses may not be performed in the exact order shown and described.The specific operations may not be performed in one continuous series ofoperations, and different specific operations may be performed indifferent embodiments. Furthermore, the process could be implementedusing several sub-processes, or as part of a larger macro process.

Also, while traffic congestion is displayed along or over roads that arepresented in a map that is being browsed in several of the exampleabove, one of ordinary skill will realize that in some embodimentstraffic congestion can be displayed during route navigation. Thus, oneof ordinary skill in the art would understand that the invention is notto be limited by the foregoing illustrative details, but rather is to bedefined by the appended claims.

What is claimed is:
 1. A non-transitory machine readable medium storinga mapping program executable by at least one processing unit associatedwith a computing device, the program comprising sets of instructionsfor: providing a display area for displaying a map having a plurality ofroads, the display area being rendered on a display device associatedwith the computing device; defining a linking layer to correlate dynamictraffic data with static road data, wherein the linking layer isrepresented as a linking traffic tile, the traffic data is representedas dynamic traffic tile, and the road data is represented as a staticroad tile; receiving a view tile request for a view of a portion of themap on the display device; building a first view tile, that correspondsto the view tile request, further comprising identifying a dynamictraffic tile, a linking traffic tile, and a static road tile thatcorresponds to the view tile request rendering, on the map, by the firstview tile, representations of traffic congestion along the roads,wherein the set of instructions for building comprises sets ofinstructions for: drawing dashed lines with a first appearance torepresent traffic for a road segment that has heavy congestion; drawingdashed lines with a second appearance to represent traffic for a roadsegment that has moderate congestion, wherein the set of instructionsfor drawing traffic congestion representation does not draw anyrepresentation of traffic for a road segment that has less than moderatetraffic congestion; detecting, through a touch interface associated withthe computing device, a touch input gesture involving at least onefinger with respect to the map; in response to the touch input gesture,dragging the map to display a different portion of the map on thedisplay device; and rendering, on the different portion of the map, by asecond view tile, representations of traffic congestion along roads inthe different portion of the map.
 2. The non-transitory machine readablemedium of claim 1, wherein the first and second appearances are firstand second colors.
 3. The non-transitory machine readable medium ofclaim 1, wherein the set of instruction for drawing traffic congestionrepresentations comprises a set of instructions for rendering the mapwith the plurality of roads and rendering graphical objects on the mapto indicate road conditions other than traffic congestion.
 4. Thenon-transitory machine readable medium of claim 1, wherein the set ofinstruction for drawing traffic congestion representations comprises aset of instructions for rendering a perspective view of athree-dimensional (3D) map scene in which the plurality of roads and thetraffic congestion representations are graphical objects within the 3Dmap scene.
 5. The non-transitory machine readable medium of claim 1,wherein the set of instructions for drawing the traffic congestionrepresentation comprises sets of instructions for: drawing the trafficcongestion representations along and adjacent to a particular roadsegment when the map is displayed at a first zoom level; and drawing thetraffic congestion representations over the particular road segment whenthe map is displayed in a second different zoom level.
 6. Thenon-transitory machine readable medium of claim 5, wherein the set ofinstruction for drawing traffic congestion representations comprises aset of instructions for drawing a traffic congestion representationalong and adjacent to the particular road segment when the first zoomlevel is lower than the second zoom level.
 7. The non-transitory machinereadable medium of claim 5, wherein the set of instruction for drawingtraffic congestion representations does not draw the traffic congestionrepresentations at any zoom level when a selectable control for enablingthe display of traffic congestion has not been previously selected. 8.The non-transitory machine readable medium of claim 5, wherein the setof instruction for drawing traffic congestion representations comprisesa set of instructions for drawing a traffic congestion representationalong and adjacent to the particular road segment when the map is beingdisplayed at a third zoom level that is between the first zoom level andthe second zoom level.
 9. The non-transitory machine readable medium ofclaim 5, wherein the first zoom level will result in the particular roadsegment being too narrow to be laid over by the traffic congestionrepresentation.
 10. A non-transitory machine readable medium storing amapping program executable by at least one processing unit of acomputing device, the mapping program comprising sets of instructionsfor: providing a first display area for displaying a map comprising aplurality of roads, the first display area being rendered on a displaydevice associated with the computing device; drawing, along theplurality of roads, (i) traffic congestion representations and (ii)selectable graphical indicators relating to road conditions other thantraffic congestion; receiving a selection of a particular graphicalindicator by a user; providing, upon selection of the particulargraphical indicator, a banner over the graphical indicator, the bannerproviding (i) information about a road condition other than trafficcongestion associated with the selected graphical indicator and (ii) aselectable control for providing additional information about the roadcondition; wherein the mapping program comprising sets of instructionsfor: defining a linking layer to correlate dynamic traffic data withstatic road data, wherein the linking layer is represented as a linkingtraffic tile, the traffic data is represented as dynamic traffic tile,and the road data is represented as a static road tile; receiving a viewtile request for a view of a portion of the map; building a first viewtile, that corresponds to the view tile request, further comprisingidentifying a dynamic traffic tile, a linking traffic tile, and a staticroad tile that corresponds to the view tile request; rendering, on themap, by the first view tile, representations of traffic congestion alongthe roads; detecting, through a touch interface associated with thecomputing device, a touch input gesture involving at least one fingerwith respect to the map; in response to the touch input gesture,dragging the map to display a different portion of the map in the firstdisplay area; and rendering, on the different portion of the map, by asecond view tile, representations of traffic congestion along roads inthe different portion of the map.
 11. The non-transitory machinereadable medium of claim 10, wherein the program further comprises setsof instructions for: selecting the selectable control in the banner; andproviding, upon selection of the selectable control, a second displayarea for displaying additional information about the road condition. 12.The non-transitory machine readable medium of claim 11, wherein thesecond display area partially overlaps the first display area.
 13. Thenon-transitory machine readable medium of claim 11, wherein the seconddisplay area fully overlaps the first display area.
 14. Thenon-transitory machine readable medium of claim 11, wherein theadditional information comprise detailed description of the roadcondition.
 15. The non-transitory machine readable medium of claim 10,wherein the road conditions comprise at least one of a road accident, aroad construction, a road closing, and a road hazard.
 16. Thenon-transitory machine readable medium of claim 10, wherein the trafficrepresentations comprise a first traffic representation that is in afirst color for a first traffic congestion and a second trafficrepresentation that is in a second color for a second trafficcongestion.
 17. The non-transitory machine readable medium of claim 10,wherein the banner displays a label for the selected graphicalindicator.